Potential detecting circuit for determining whether a detected potential has reached a prescribed level

ABSTRACT

A potential detecting circuit is provided for detecting prescribed potential and determining whether the detected prescribed potential has reached a prescribed level. The circuit includes an output node; a reference current supply for supplying a prescribed reference current to the output node; a detection node for receiving the prescribed potential; a comparing current supply circuit responsive to the prescribed potential applied to the detection node for supplying a comparing current to the output node; and a transistor having a control electrode receiving a reference potential which is independent of a power supply voltage and is at a level different from a power supply potential. The transistor has one conduction electrode connected to the detection node and the other conduction electrode connected to the comparing current supply circuit. Current change in the transistor, corresponding to a change in the prescribed potential applied to the detection node, changes the comparing current. Accordingly, current consumption may be reduced, and a stable detection level may be maintained, which is not dependent on fluctuations in temperature or fluctuations in a power supply potential applied to the circuit.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of application Ser. No. 09/126,709 filed Jul. 31, 1998 now U.S. Pat. No. 6,351,178, which a division of Ser. No. 08/755,933 filed on Nov. 25, 1996, now U.S. Pat. No. 5,847,597, which is a continuation of application Ser. No. 08/393,798 filed Feb. 24, 1995, now abandoned. The application Ser. No. 08/190,329, filed on Jan. 31, 1994 has been issued as U.S. Pat. No. 5,610,550.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a reference potential generating circuit, a potential detecting circuit and a semiconductor integrated circuit device. More specifically, it relates to an intermediate potential generating circuit used in a semiconductor memory device, an internal potential detecting circuit for controlling an internal potential generating circuit used in a semiconductor memory device, and to a semiconductor integrated circuit device including the internal potential generating circuit.

2. Description of the Background Art

FIG. 81 is a schematic diagram showing a main structure of a dynamic random access memory (hereinafter referred to as a “DRAM”) which is one of semiconductor memory devices.

Referring to FIG. 81, the DRAM includes a bit line pair BL and /BL, word lines WL arranged in a direction orthogonal to the bit line pair BL and /BL, line BLI arranged orthogonal to the bit line pair BL and /BL for controlling connection/disconnection of a sense amplifier and an array side, memory cells arranged corresponding to crossings between bit line pair BL and /BL and word lines WL, sense amplifiers SAn and SAp amplifying the voltage generated between the bit line pair BL and /BL, and a precharge circuit PC for precharging the bit line pair BL and /BL to an intermediate potential (½) Vcc of the power supply potential Vcc.

The memory cell MC includes a transfer gate TG and a capacitor C, and it is adapted such that when the potential at word line WL rises, data generated on the bit line pair BL and /BL is written to the capacitor C, or the data stored in capacitor C is read to bit line pair BL and /BL.

Sense amplifiers SAn and SAp are formed by an N channel sense amplifier SAn and a P channel sense amplifier SAp. N channel sense amplifier SAn includes cross coupled two N channel MOS transistors. P channel sense amplifier SAp includes two cross coupled P channel MOS transistors.

Precharge circuit PC supplies the intermediate potential (½) Vcc from precharge line VBL to bit line pair BL and /BL, and equalizes both potentials of the bit line pair BL and /BL in response to a control signal from a equalizing line EQ.

Reading operation of the DRAM will be described with reference to a timing chart of FIG. 82.

Before reading the data, bit line pair BL and /BL are precharged to the intermediate potential (½) Vcc. Then, when the potential of the word line WL increases to the boosted potential Vpp, the data in capacitor C is read to bit line BL through transfer gate TG, and therefore the potential of the bit line BL is shifted to the power supply potential Vcc or the ground potential Vss.

Then, when transfer gates S0 and /S0 (not shown) connected to sense amplifier driving lines SN and SP are rendered conductive, the potential of bit line BL attains to the ground potential Vss and the potential of bit line /BL attains to the power supply potential Vcc, for example.

As described above, in the DRAM, it is necessary to precharge the bit line pair BL and /BL to the intermediate potential (½) Vcc.

FIG. 83 is a schematic diagram showing the whole structure of a conventional intermediate potential generating circuit disclosed in U.S. Pat. No. 4,788,455.

Referring to FIG. 83, the intermediate potential generating circuit includes a reference potential generating stage 1 generating a reference potential V_(ref) 1, a reference potential generating stage 2 generating a reference potential V_(ref) 2, an output stage 3 responsive to these reference potential V_(ref) 1 and V_(ref) 2 for generating an intermediate potential (½) Vcc, and an output node 4.

Reference potential generating stage 1 includes a resistance element 1 a, an N channel MOS transistor 1 b, an N channel MOS transistor 1 c and a resistance element 1 d connected in series between a power supply node 100 to which the power supply potential Vcc is applied and a ground node 200 to which the ground potential Vss is applied. Reference potential generating stage 2 includes a resistance element 2 a, a P channel MOS transistor 2 b, a P channel MOS transistor 2 c and a resistance element 2 d connected in series between power supply node 100 and ground node 200. Output stage 3 includes an N channel MOS transistor 3 a and a P channel MOS transistor 3 b connected in series between power supply node 100 and ground node 200.

The reference potential V_(ref) 1 generated at node N1 is determined by a threshold voltage V_(tn) of diode connected N channel MOS transistor 1 b. The reference potential V_(ref) 2 generated at node N2 is determined by the absolute value |V_(tp)| of the threshold voltage of diode connected P channel MOS transistor 2 c.

Therefore, at the gate electrode of N channel MOS transistor 3 a in output stage 3, a voltage (½) Vcc+V_(tn) higher than the intermediate potential by the threshold voltage is applied. To the gate electrode of P channel MOS transistor 3 b, a potential (½) Vcc−|V_(tp)| lower than the intermediate potential by the absolute value of the threshold voltage is applied. Therefore, an intermediate potential (½) Vcc is generated as the output potential V_(out) at output node 4.

FIG. 85 shows the whole structure of an intermediate potential generating circuit shown in FIG. 4 of Japanese Patent Laying-Open No. 63-174115.

Referring to FIG. 85, the intermediate potential generating circuit includes reference potential generating stage 5 for generating two reference potentials, an output stage 3 and an output node 4. The output stage 3 is the same as that shown in FIG. 83.

The reference potential generating stage 5 of the intermediate potential generating circuit includes a P channel MOS transistor 5 a having its gate elect-code connected to ground node 200, a diode connected N channel MOS transistor 5 b, a diode connected P channel MOS transistor 5 c, and an N channel MOS transistor 5 d having its gate connected to power supply node 100.

Similar to the one described above, in this intermediate potential generating circuit, a potential higher than the intermediate potential by the threshold voltage is applied to the gate electrode of N channel MOS transistor 3 a in output stage 3, and a potential lower than the intermediate potential by the absolute value of the threshold voltage is applied to the gate electrode of P channel MOS transistor 3 b, and hence the intermediate potential (½) Vcc is generated at the output node 4.

FIG. 86 is a schematic diagram showing an example of a boosted potential detecting circuit used in a DRAM. The boosted potential Vpp is supplied as power supply to a word driver driving a word line, for example. Referring to FIG. 86, the boosted potential detecting circuit includes P channel MOS transistors 6 a to 6 d connected in series between a detecting node 804 and ground node 200, and an inverter 7. Transistors 6 a to 6 d are each diode connected. Inverter 7 consists of P channel MOS transistor 7 a and an N channel MOS transistor 7 b.

In the boosted potential detecting circuit, when the potential at node NA is lower than the logical threshold value of inverter 7, an enable signal GE at the H (logic high) level is generated at output node 801. In response to the H level enable signal GE, the boosted potential generating circuit (not shown) is activated. Meanwhile, when the potential at node NA becomes higher than the logical threshold value of inverter 7, an enable signal GE at the L (logic low) level is generated at output node 801. In response to the L level enable signal GE, the boosted potential generating circuit is inactivated.

However, in the intermediate potential generating circuit shown in FIG. 83, in order to reduce through current flowing from power supply node 100 to ground node 200 in reference potential generating stage 1, the values of resistance elements 1 a and 1 d must be set as high as several MΩ. The same applies to reference potential generating stage 2.

In contrast, in the DRAM, in order to increase the speed of signal transmission, interconnection material having smaller resistance value per unit length tends to be used. Therefore, when such a material that has small resistance value per unit length is used for forming the resistance elements 1 a, 1 d, 2 a and 2 d, the layout area would be considerably large.

FIG. 84 is a graph showing time change of potentials at various nodes immediately after power on of the intermediate potential generating circuit shown in FIG. 83.

Referring to FIG. 84, when the power is turned on, initially the potential at power supply node 100 gradually increases from 0V to Vcc. The dotted line in the graph represents half the potential of the power supply node 100.

Since resistance element 1 a of reference potential generating stage 1 has very large value, the potential at node N1 does not rapidly increase even when the potential at power supply node 100 increases. Further, since resistance element 2 a in reference potential generating stage 2 also has large value, the potential at node N2 does not rapidly increase, either. Therefore, it takes very long for the output potential V_(out) to reach the intermediate potential (½) Vcc.

The current I flowing in reference potential generating stage 5 of the intermediate potential generating circuit shown in FIG. 85 is represented by the following equation (1):

I=β _(p)(Vcc−V _(tn))(Vcc−V _(tp))  (1)

where β_(p) represents the degree of movement of holes in P channel MOS transistor. V_(tn) represents the threshold voltage of the N channel MOS transistor. V_(tp) represents the threshold voltage of the P channel MOS transistor.

In the intermediate potential generating circuit, when the current I represented by the equation (1) flows in reference potential generating stage 5, the intermediate potential (½) Vcc is generated at output node 4. Therefore, the current I does not have the desired value unless the threshold voltages V_(tn) and V_(tp) are set accurately, causing deviation of the output potential V_(out) from the intermediate potential (½) Vcc.

FIG. 3 is a graph showing a result of simulation of output potential V_(out) with respect to the deviation of the threshold voltage V_(tn), when the power supply potential Vcc is set to 2.5V. As is apparent from the graph, when the threshold voltage V_(tn), deviates, the output potential V_(out) varies significantly.

In the boosted potential detecting circuit shown in FIG. 86, when the power supply potential Vcc fluctuates, the logical threshold value of inverter 7 varies, and therefore the detection level of the boosted potential detecting circuit is not stable. Further, since the boosted potential Vpp is applied to node NA through diode connected three transistors 6 a to 6 c, the detection level of the boosted potential detecting circuit also varies when the operational temperature varies. This is because the threshold voltage of the transistor varies when the operational temperature changes. Since three transistors are connected in series in the boosted potential detecting circuit, the fluctuation of the threshold voltage is amplified three times.

SUMMARY OF THE INVENTION

An object of the present invention is to provide a reference potential generating circuit which is capable of generating more stable reference potential.

Another object of the present invention is to provide a reference potential generating circuit capable of generating a desired reference potential accurately.

A still further object of the present invention is to provide a reference potential generating circuit capable of generating a desired reference potential quickly after power on.

A still further object of the present invention is to provide a reference potential generating circuit of which layout area is sufficiently small.

A still further object of the present invention is to provide an internal potential detecting circuit having a stable detection level.

A still further object of the present invention is to provide an internal potential detecting circuit of which detection level does not fluctuate with the fluctuation of the power supply potential.

A still further object of the present invention is to provide an internal potential detecting circuit of which detection level does not fluctuate with the fluctuation of operational temperature.

The reference potential generating circuit according to one aspect of the present invention is for generating a reference potential between a first potential and a second potential, and it includes an output node, a first transistor of a first conductivity type, for example, an N channel MOS transistor, a first transistor of a second conductivity type, for example a P channel MOS transistor, a second transistor of the second conductivity type, a second transistor of the first conductivity type, a third transistor of the first conductivity type and a third transistor of the second conductivity type. The aforementioned reference potential is generated at the output node. The aforementioned first transistor of the first conductivity type has one conduction electrode connected to the output node, and another conduction electrode connected to a first node to which a third potential is applied. The first transistor of the second conductivity type has one conduction electrode connected to the output node, and another conduction electrode connected to a second node to which a fourth potential is applied. The second transistor of the second conductivity type has one conduction electrode connected to a third node to which the first potential is applied, another conduction electrode connected to a control electrode of the first transistor of the first conductivity type, and a control electrode connected to the output node. The second transistor of the first conductivity type has one conduction terminal connected to a fourth node to which the second potential is applied, another conduction electrode connected to a control electrode of the first transistor of the second conductivity type, and a control electrode connected to the output node. The third transistor of the first conductivity type has one conduction electrode, and another conduction electrode and a control electrode connected to each other and to said another conduction electrode of the second transistor of the second conductivity type. The third transistor of the second conductivity type has one conduction electrode connected to the aforementioned one conduction electrode of the third transistor of the first conductivity type, and another conduction electrode and a control electrode connected to each other and to the aforementioned another conduction electrode of the second transistor of the first conductivity type.

The reference potential generating circuit according to another aspect of the present invention includes an output node, a transistor of a first conductivity type, for example a P channel MOS transistor, an output resistance element, and a control potential generating circuit. A reference potential is generated at the output node. The transistor of the first conductivity type has one conduction electrode connected to a first node to which the first potential is applied, and another conduction electrode connected to the aforementioned output node. The output resistance element is connected between the output node and a second node to which a second potential is applied. The control potential generating circuit includes a first path from a third node to which a third potential is applied to a fourth node to which a fourth potential is applied; a second path from a fifth node to which a fifth potential is applied to a sixth node to which a sixth potential is applied; a first current mirror circuit responsive to a current flowing through the first path for controlling current flowing through the second path; a second current mirror circuit responsive to the current flowing through the second path for controlling the current flowing through the first path; a control node positioned in the first path between the first and second current mirror circuits and connected to the control electrode of the transistor of the first conductivity type; a first resistance element connected in the first path between the control node and the first current mirror circuit; and a second resistance element connected in the first path between the second current mirror circuit and the fourth node.

According to a still further aspect of the present invention, the potential detecting circuit detects a potential to be detected, and determines whether or not the detected internal potential has reached a prescribed detection level, and it includes an output node, a reference current supplying circuit, a detection node, and comparing current supplying circuit. The reference current supplying circuit supplies a prescribed reference current to the output node. To the detection node, a potential to be detected is applied. The comparing current supplying circuit supplies a comparing current to the output node, in response to the potential applied to the detection node. At this time, when a positive reference current is applied to the output node, a negative comparing current is supplied to the output node. Conversely, when a negative reference current is supplied to the output node, a positive comparing current is applied to the output node.

Therefore, in the reference potential generating circuit described above, the reference potential generated at the output node is fed back to the control electrode of the second transistor of the second conductivity type and the control electrode of the second transistor of the first conductivity type, and therefore even when the reference potential varies, it quickly returns to the original value. Therefore, a more stable reference potential can be generated. When the power is turned on, initially the potential at the output node is 0V. This potential is also fed back to the control electrode of the second transistor of the second conductivity type and the control electrode of the second transistor of the first conductivity type. Therefore, the potential at the output node quickly attains the reference potential. Further, the second transistor of the second conductivity type and the third transistor of the first conductivity type are arranged in symmetry with respect to the second transistor of the first conductivity type and the third transistor of the second conductivity type. Therefore, the potential at the node at which one conduction electrode of the third transistor of the first conductivity type and one conduction electrode of the third transistor of the second conductivity type are connected to each other assumes exactly the intermediate potential between the first and second potentials. Therefore, an accurate intermediate potential can be generated as the reference potential. Further, since the second transistor of the second conductivity type and the second transistor of the first conductivity type are used for supplying current to the third transistor of the first conductivity type and the third transistor of the second conductivity type, the layout area can be reduced as compared with an example employing a resistance element.

In the reference potential generating circuit according to another aspect of the present invention, when the value of the first resistance element is appropriately changed, the control potential supplied to the control electrode of the transistor of the first conductivity type varies in response to the change of the resistance value, and therefore current flowing through the output resistance element also varies. Therefore, the desired reference potential can be generated at the output node.

In the internal potential detecting circuit according to the still further aspect of the present invention, the relation of magnitude of the reference current and a comparing current varies in response to the internal potential applied to the detection node. Therefore, when the internal potential attains to the detection level, the potential at the output node changes.

The foregoing and other objects, features, aspects and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram showing a whole structure of an intermediate potential generating circuit in accordance with Embodiment 1 of the present invention.

FIG. 2 is a graph showing the manner of change of potentials at various nodes with time, immediately after power on of the intermediate potential generating circuit shown in FIG. 1.

FIG. 3 is a graph showing a manner of change of the output potential with respect to deviation of the threshold voltage of a transistor in the intermediate potential generating circuit shown in FIG. 1.

FIG. 4 is a block diagram showing a whole structure of the intermediate potential generating circuit in accordance with Embodiment 2 of the present invention.

FIG. 5 is a schematic diagram showing a whole structure of an intermediate potential generating circuit in accordance with Embodiment 3 of the present invention.

FIG. 6 is a block diagram showing a whole structure of an intermediate potential generating circuit in accordance with Embodiment 4 of the present invention.

FIG. 7 is a cross section showing a transistor structure in an intermediate potential generating circuit in accordance with Embodiment 5 of the present invention.

FIG. 8 is a schematic diagram showing a whole structure of an intermediate potential generating circuit in accordance with Embodiment 6 of the present invention.

FIG. 9 is a cross section showing a structure of a memory cell of a DRAM.

FIG. 10 is a graph showing relation between power supply potentials in a hierarchical power supply method.

FIG. 11 is a schematic diagram showing a whole structure of an intermediate potential generating circuit in accordance with Embodiment 7 of the present invention.

FIG. 12 shows a concept of a basic reference potential generating circuit in the intermediate potential generating circuit in accordance with Embodiment 7 of the present invention.

FIG. 13 is a schematic diagram showing specific structure of a constant current source in the basic reference potential generating circuit shown in FIG. 12.

FIG. 14 is a graph showing relations between various power supply potentials in the intermediate potential generating circuit employing the basic reference potential generating circuit shown in FIGS. 12 and 13.

FIG. 15 is a schematic diagram showing a structure of an intermediate potential generating circuit in accordance with Embodiment 8 of the present invention.

FIG. 16 is a schematic diagram showing a structure of an intermediate potential generating circuit in accordance with Embodiment 9 of the present invention.

FIG. 17 shows a concept of a basic reference potential generating circuit in an intermediate potential generating circuit in accordance with Embodiment 10 of the present invention.

FIG. 18 is a schematic diagram showing a specific structure of the basic reference potential generating circuit shown in FIG. 17.

FIG. 19 is a schematic diagram showing a whole structure of a basic reference potential generating circuit in an intermediate potential generating circuit in accordance with Embodiment 11 of the present invention.

FIG. 20 is a schematic diagram showing a whole structure of a basic reference potential generating circuit in an intermediate potential generating circuit in accordance with Embodiment 12 of the present invention.

FIG. 21 is a schematic diagram showing a whole structure of a basic reference potential generating circuit in an intermediate potential generating circuit in accordance with Embodiment 13 of the present invention.

FIG. 22 is a schematic diagram showing a whole structure of a basic reference potential generating circuit in an intermediate potential generating circuit in accordance with Embodiment 14 of the present invention.

FIG. 23 is a graph showing general operational characteristics of an MOS transistor.

FIG. 24 is a schematic diagram showing a whole structure of a basic reference potential generating circuit in an intermediate potential generating circuit in accordance with Embodiment 15 of the present invention.

FIG. 25 is a schematic diagram showing a whole structure of a basic reference potential generating circuit in an intermediate potential generating circuit in accordance with Embodiment 16 of the present invention.

FIG. 26 is a schematic diagram showing a whole structure of a basic reference potential generating circuit in an intermediate potential generating circuit in accordance with Embodiment 17 of the present invention.

FIG. 27 is a schematic diagram showing a whole structure of a basic reference potential generating circuit in an intermediate potential generating circuit in accordance with Embodiment 18 of the present invention.

FIG. 28 is a schematic diagram showing a whole structure of a basic reference potential generating circuit in an intermediate potential generating circuit in accordance with Embodiment 19 of the present invention.

FIG. 29 is a schematic diagram showing a whole structure of a basic reference potential generating circuit in an intermediate potential generating circuit in accordance with Embodiment 20 of the present invention.

FIG. 30 is a schematic diagram showing a structure of a part of an intermediate potential generating circuit in accordance with Embodiment 21 of the present invention.

FIG. 31 is a schematic diagram showing a structure of a part of an intermediate potential generating circuit in accordance with Embodiment 22 of the present invention.

FIG. 32 is a schematic diagram showing a whole structure of an intermediate potential generating circuit in accordance with Embodiment 23 of the present invention.

FIG. 33 is a schematic diagram showing a structure of a part of an intermediate potential generating circuit in accordance with Embodiment 24 of the present invention.

FIG. 34 is a schematic diagram showing a structure of an internal potential detecting circuit in accordance with Embodiment 25 of the present invention.

FIG. 35 is a schematic diagram showing a specific structure of the internal potential generating circuit shown in FIG. 34.

FIG. 36 is a schematic diagram showing a structure of an internal potential detecting circuit in accordance with Embodiment 26 of the present invention.

FIG. 37 is a schematic diagram showing a specific structure of the internal potential detecting circuit shown in FIG. 36.

FIG. 38 is a schematic diagram showing a structure of an internal potential detecting circuit in accordance with Embodiment 27 of the present invention.

FIG. 39 is a schematic diagram showing a structure of an internal potential detecting circuit in accordance with Embodiment 28 of the present invention.

FIG. 40 is a schematic diagram showing a structure of an internal potential detecting circuit in accordance with Embodiment 29 of the present invention.

FIG. 41 is a schematic diagram showing a structure of an internal potential detecting circuit in accordance with Embodiment 30 of the present invention.

FIG. 42 is a schematic diagram showing a structure of an internal potential detecting circuit in accordance with Embodiment 31 of the present invention.

FIG. 43 is a schematic diagram showing a structure of an internal potential detecting circuit in accordance with Embodiment 32 of the present invention.

FIG. 44 is a schematic diagram showing a structure of an internal potential detecting circuit in accordance with Embodiment 33 of the present invention.

FIG. 45 is a schematic diagram showing a specific structure of an internal potential detecting circuit shown in FIG. 44.

FIG. 46 is a schematic diagram showing a structure of a substrate potential detecting circuit in accordance with Embodiment 34 of the present invention.

FIG. 47 is a schematic diagram showing a whole structure of a substrate potential detecting circuit shown in FIG. 46.

FIG. 48 is a waveform diagram showing an operation of the substrate potential detecting circuit shown in FIGS. 46 and 47.

FIG. 49 is a graph showing relation between the power supply potential and detecting level of the substrate potential detecting circuit shown in FIGS. 46 and 47.

FIG. 50 is a schematic diagram showing a structure of internal potential detecting circuit in accordance with Embodiment 35 of the present invention.

FIG. 51 is a schematic diagram showing a specific structure of an internal potential detecting circuit shown in FIG. 50.

FIG. 52 is a schematic diagram showing a structure of a boosted potential detecting circuit in accordance with Embodiment 36 of the present invention.

FIG. 53 is a schematic diagram showing the whole structure of the boosted potential detecting circuit shown in FIG. 52.

FIG. 54 is a diagram of waveforms showing the operation of the boosted potential detecting circuit shown in FIGS. 52 and 53.

FIG. 55 is a schematic diagram showing a whole structure of a substrate potential detecting circuit in accordance with Embodiment 37 of the present invention.

FIG. 56 is a schematic diagram showing a whole structure of a substrate potential detecting circuit in accordance with Embodiment 38 of the present invention.

FIG. 57 is a schematic diagram showing a structure of a boosted potential detecting circuit in accordance with Embodiment 39 of the present invention.

FIG. 58 is a schematic diagram showing a structure of an internal potential detecting circuit in accordance with Embodiment 40 of the present invention.

FIG. 59 is a schematic diagram showing a structure of an internal potential detecting circuit in accordance with Embodiment 41 of the present invention.

FIG. 60 is a schematic diagram showing a whole structure of a substrate potential detecting circuit in accordance with Embodiment 42 of the present invention.

FIG. 61 is a schematic diagram showing a whole structure of a boosted potential detecting circuit in accordance with Embodiment 43 of the present invention.

FIG. 62 is a schematic diagram showing a whole structure of a substrate potential detecting circuit in accordance with Embodiment 44 of the present invention.

FIG. 63 is a schematic diagram showing a whole structure of a boosted potential detecting circuit in accordance with Embodiment 45 of the present invention.

FIG. 64 is a schematic diagram showing a whole structure of an internal potential detecting circuit in accordance with Embodiment 46 of the present invention.

FIG. 65 is a block diagram showing a part of a DRAM in accordance with Embodiment 47 of the present invention.

FIG. 66 is a graph showing relation between power supply potential, reference potential and detection level of a boosted potential detecting circuit in the DRAM shown in FIG. 65.

FIG. 67 is a block diagram showing a part of a DRAM in accordance with Embodiment 48 of the present invention.

FIG. 68 is a graph showing two detection levels of two boosted potential detectors and relation between reference potentials therefor and external power supply potential, in the DRAM shown in FIG. 67.

FIG. 69 is a block diagram showing a part of a DRAM in accordance with Embodiment 49 of the present invention.

FIG. 70 is a block diagram showing a part of a DRAM in accordance with Embodiment 50 of the present invention.

FIG. 71 is a block diagram showing a whole structure of a DRAM in accordance with Embodiment 51 of the present invention.

FIG. 72 is a block diagram showing a whole structure of a DRAM in accordance with Embodiment 52 of the present invention.

FIG. 73 is a block diagram showing a whole structure of a DRAM in accordance with Embodiment 53 of the present invention.

FIG. 74 is a block diagram showing a whole structure of a DRAM in accordance with Embodiment 54 of the present invention.

FIG. 75 is a block diagram showing a whole structure of a DRAM in accordance with Embodiment 55 of the present invention.

FIG. 76 is a block diagram showing a whole structure of a DRAM in accordance with Embodiment 56 of the present invention.

FIG. 77 is a schematic diagram showing principle of an internal potential detecting circuit in accordance with Embodiment 57 of the present invention.

FIG. 78 is a schematic diagram showing a specific structure of the internal potential detecting circuit shown in FIG. 77.

FIG. 79 is an illustration showing principle of an internal potential detecting circuit in accordance with Embodiment 58 of the present invention.

FIG. 80 is a schematic diagram showing a specific structure of the internal potential detecting circuit shown in FIG. 79.

FIG. 81 is a schematic diagram showing a main structure of a conventional DRAM.

FIG. 82 is a timing chart showing an operation of the DRAM shown in FIG. 81.

FIG. 83 shows a whole structure of a conventional intermediate potential generating circuit.

FIG. 84 is a graph showing the manner of change of potentials at various nodes with time, immediately after power on of the intermediate potential generating circuit shown in FIG. 83.

FIG. 85 is a schematic diagram showing a whole structure of another conventional intermediate potential generating circuit.

FIG. 86 is a schematic diagram showing a structure of a conventional boosted potential detecting circuit.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Embodiments of the present invention will be described in detail with reference to the figures. In the figures, the same reference characters denote the same or corresponding portions.

[Embodiment 1]

FIG. 1 is a circuit diagram showing the whole structure of an intermediate potential generating circuit in accordance with Embodiment 1 of the present invention.

Referring to FIG. 1, the intermediate potential generating circuit includes a reference potential generating stage 10 for generating two reference potentials V_(ref) 1 and V_(ref) 2, an output stage 12 responsive to these reference potentials V_(ref) 1 and V_(ref) 2 for generating an intermediate potential (½) Vcc between power supply potential Vcc and ground potential Vss, and an output node 14.

Reference potential generating stage 10 includes a P channel MOS transistor 101, an N channel MOS transistor 102, a P channel MOS transistor 103 and an N channel MOS transistor 104. These transistors 101 to 104 are connected in series between a power supply node 100 to which power supply potential Vcc is applied, and ground node 200 to which ground potential Vss is applied.

P channel MOS transistor 101 has a source electrode connected to power supply node 100 and a gate electrode connected to output node 14. A back gate electrode is commonly connected to the source electrode.

N channel MOS transistor 102 has drain and gate electrodes connected to drain electrode of P channel MOS transistor 101. These drain and gate electrodes are connected to each other. Namely, N channel MOS transistor 102 is diode connected.

P channel MOS transistor 103 has its source electrode connected to source electrode of N channel MOS transistor, 102, and drain and gate electrodes connected to each other. Namely, P channel MOS transistor 103 is diode connected. The back gate electrode is commonly connected to the source.

N channel MOS transistor 104 has its drain electrode connected to the source and gate electrodes of P channel MOS transistor 103, its source electrode connected to ground node 200, and its gate electrode connected to output node 14.

To the back gates of N channel MOS transistors 102 and 104, a substrate potential V_(BB) which is lower than the ground potential Vss is applied. The structure of P channel MOS transistor 101 is identical with that of P channel MOS transistor 103. N channel MOS transistor 102 has identical structure as N channel MOS transistor 104.

Output stage 12 includes an N channel MOS transistor 121 and a P channel MOS transistor 122. These transistors 121 and 122 are connected in series between power supply node 100 and ground node 200.

N channel MOS transistor 121 has its drain electrode connected to power supply node 100, its source electrode connected to output node 14, and gate electrode connected to the drain and gate electrodes of N channel MOS transistor 102. The threshold voltage of N channel MOS transistor 121 is approximately equal to or larger than the threshold voltage V_(tn) of N channel MOS transistor 102.

P channel MOS transistor 122 has a source electrode connected to output node 14, drain electrode connected to ground node 200, and gate electrode connected to the drain and gate electrodes of P channel MOS transistor 103. The threshold voltage of P channel MOS transistor 122 is set to be equal to or larger than the absolute value |V_(tp)| of the threshold voltage of P channel MOS transistor 103.

The operation of the intermediate potential generating circuit will be described in detail.

In reference potential generating stage 10, four transistors 101 to 104 are arranged in symmetry with node N3 being the center, and therefore an intermediate potential (½) Vcc exactly in the middle of power supply potential Vcc and ground potential Vss is generated at node N3.

Further, since N channel MOS transistor 102 is diode connected, a potential (½) Vcc+V_(tn) higher than the potential at node N3, that is, higher than the intermediate potential by the threshold voltage V_(tn) is generated at node N1, as reference potential V_(ref) 1.

Meanwhile, since P channel MOS transistor 103 is also diode connected, a potential (½) Vcc−|V_(tp)| lower than the potential at node N3, that is, lower than the intermediate potential by the absolute value of the threshold voltage |V_(tp)| is generated at node N2, as reference potential V_(ref) 2.

The reference potential V_(ref) 1 generated in reference potential generating stage 10 is applied to the gate electrode of N channel MOS transistor 121 of output stage 12. Reference potential V_(ref) 2 is applied to the gate electrode of P channel MOS transistor 122.

Since the threshold voltage of N channel MOS transistor 121 is set equal to or slightly larger than the threshold voltage of N channel MOS transistor 102, N channel MOS transistor 121 is slightly rendered conductive. Since the absolute value of the threshold voltage of P channel MOS transistor 122 is set to be equal to or slightly larger than the absolute value |V_(tp)| of the threshold voltage of P channel MOS transistor 103, P channel MOS transistor 121 is also slightly rendered conductive.

In this output stage 12 also, since transistors 121 and 122 are arranged in symmetry, an intermediate potential (½) Vcc is generated at output node 14.

An operation when the potential at output node 14 (hereinafter referred to as “output potential”) V_(out) is to be shifted from the intermediate potential (½) Vcc in the intermediate potential generating circuit will be described.

When the output potential V_(out) lowers, the gate potential with respect to the source potential rises in N channel MOS transistor 121, and therefore conduction resistance of N channel MOS transistor 121 decreases, and a current flows from power supply node 100 through transistor 121 to output node 14. Therefore, output potential V_(out) rises.

Further, at this time, the output potential V_(out) is applied to the gate electrode of P channel MOS transistor 101, and hence conduction resistance of transistor 101 decreases and a current flows from power supply node 100 through transistor 101 to node N1. Therefore, when output potential V_(out) lowers, the gate potential of N channel MOS transistor 121 increases quickly, and thus output potential V_(out) quickly returns to the original intermediate potential (½) Vcc.

Meanwhile, if output potential V_(out) rises, gate potential with respect to the source potential decreases in P channel MOS transistor 122, and therefore conduction resistance of transistor 122 decreases. Therefore, output potential V_(out) lowers.

Further, since the output potential V_(out) is applied to the gate electrode of N channel MOS transistor 104 at this time, conduction resistance of transistor 104 decreases, and the potential at node N2 lowers quickly. Therefore, when the output potential V_(out) rises from the intermediate potential (½) Vcc, it returns to the original value quickly.

In this manner, in the intermediate potential generating circuit according to Embodiment 1, since the output potential V_(out) is fed back to reference potential generating stage 10, even when output potential V_(out) deviates from the intermediate potential (½) Vcc, it quickly returns to the original intermediate potential (½) Vcc. Therefore, the intermediate potential generating circuit can generate a stable intermediate potential (½) Vcc as compared with the conventional intermediate potential generating circuit shown in FIGS. 83 and 85.

FIG. 2 is a graph showing the manner of change of potentials at nodes 100, N1, 14 and N2 with time, immediately after power on of the intermediate potential generating circuit.

Referring to FIG. 2, when power is turned on, the potential at power supply node 100 increases from 0V to power supply potential Vcc. The dotted line in FIG. 2 shows a half of the potential at power supply node 100. Since output potential V_(out) is initially at 0V, the conduction resistance of P channel MOS transistor 101 is sufficiently small. Therefore, the potential at node N1 rises quickly, and N channel MOS transistor 121 is rendered fully conductive quickly. Therefore, output potential V_(out) quickly attains one half the potential of power supply node 100. Therefore, output potential V_(out) attains the intermediate potential (½) Vcc in a short period of time from power on. Therefore, in the intermediate potential generating circuit, the intermediate potential (½) Vcc can be attained faster than in the conventional intermediate potential generating circuit shown in FIG. 83.

In reference potential generating stages 1 and 2 of the conventional intermediate potential generating circuit shown in FIG. 83, resistance elements 1 a, 1 d, 2 a and 2 d are provided. By contrast, reference potential generating stage 10 of the intermediate potential generating circuit in accordance with Embodiment 1 includes transistors 101 and 104. Therefore, larger resistance value can be realized by smaller area of occupation than resistance elements 1 a, 1 d, 2 a and 2 d. Therefore, the layout area of the intermediate potential generating circuit can be reduced from the conventional area.

FIG. 3 is a graph showing how much the output potential V_(out) deviates when the threshold voltage V_(out) of N channel MOS transistors 102 and 104 deviate from a desired threshold voltage. This graph shows the result of simulation when power supply potential Vcc is set to 2.5V.

In the intermediate potential generating circuit, when the degree of movement of the holes in N channel MOS transistor is equal to that of P channel MOS transistor, an intermediate potential (½) Vcc is generated at output node 14. Therefore, even if the threshold voltage of the transistor deviates from the desired value as in the conventional intermediate potential generating circuit shown in FIG. 85, the output potential V_(out) hardly deviates from the intermediate potential (½) Vcc. Therefore, the intermediate potential generating circuit can generate more accurate intermediate potential (½) Vcc than the prior art.

In Embodiment 1, interconnection from output node 14 to the gate electrodes of transistors 101 and 104 constitute control potential applying means for applying the intermediate potential (½) Vcc as the control potential to the gate electrodes of transistors 101 and 104.

[Embodiment 2]

FIG. 4 is a block diagram showing a whole structure of an intermediate potential generating circuit in accordance with Embodiment 2 of the present invention.

Referring to FIG. 4, the intermediate potential generating circuit includes a control potential generating circuit 20 for generating two control potentials V_(con) 1 and V_(con) 2; a reference potential generating stage 16 responsive to these control potentials V_(con) 1 and V_(con) 2 for generating two reference potentials V_(ref) 1 and V_(ref) 2; an output stage 18 responsive to these reference potentials V_(ref) 1 and V_(ref) 2 for generating an output potential V_(out); and an output node 14. Reference potential generating stage 16 includes, similar to reference potential generating stage 10 of Embodiment 1 above, a P channel MOS transistor 161, a diode connected N channel MOS transistor 162, a diode connected P channel MOS transistor 163 and an N channel MOS transistor 164, and these transistors 161 to 164 are connected in series between power supply node 100 and ground node 200.

However, different from reference potential generating stage 10 of Embodiment 1 above, control potential V_(con) 1 from control potential generating circuit 20 is applied to the gate electrode of P channel MOS transistor 161, and control potential V_(con) 2 from control potential generating circuit 20 is applied to the gate electrode of N channel MOS transistor 164.

Similar to output stage 12 of Embodiment 1 above, output stage 18 includes an N channel MOS transistor 181 and a P channel MOS transistor 182, and these transistors 181 and 182 are connected in series between power supply node and ground node 200.

However, different from output node 14 of Embodiment 1 above, the output node 14 is not connected to the gate electrodes of transistors 161 and 164 of reference potential generating stage 16.

In the intermediate potential generating circuit, when intermediate potential (½) Vcc is applied as control potentials V_(con) 1 and V_(con) 2 to the gate electrodes of transistors 161 and 164 from control potential generating circuit 20, an intermediate potential (½) Vcc is generated at output node 14 as in Embodiment 1 above. However, the intermediate potential (½) Vcc applied to the gate electrodes of transistors 161 and 164 is generated by control potential generating circuit 20, and therefore different from the intermediate potential (½) Vcc generated at output node 14, it does not fluctuate.

In the intermediate potential generating circuit, control potential generating circuit 20 can generate desired control potentials V_(con) 1 and V_(con) 2. Therefore, even if reference potential generating stage 16 is not formed symmetrically, the potential at node N3 can be set at the intermediate potential (½) Vcc. Therefore, a desired intermediate potential (½) Vcc can be generated by the intermediate potential generating circuit by adjusting the control potential generating circuit 20.

[Embodiment 3]

FIG. 5 is a circuit diagram showing a whole structure of an intermediate potential generating circuit in accordance with Embodiment 3 of the present invention.

Referring to FIG. 5, the intermediate potential generating circuit includes a reference potential generating stage 10, a first output stage 10, a second output stage 22, and an output node 14. The intermediate potential generating circuit differs from the intermediate potential generating circuit of Embodiment 1 in that a second output stage 22 is newly provided.

The second output stage 22 includes an N channel MOS transistor 221 and a P channel MOS transistor 222, and these transistors 221 and 222 are connected in series between power supply node 100 and ground node 200.

N channel MOS transistor 221 has drain electrode connected to power supply node 100, source electrode connected to output node 14 and gate electrode connected to drain and gate electrodes of N channel MOS transistor 102 in reference potential generating stage 10. The channel length of N channel MOS transistor 221 is made longer than that of N channel MOS transistor 121 in the first output stage 12. Therefore, the threshold voltage of N channel MOS transistor 221 is larger than that of N channel MOS transistor 121.

The channel width of N channel MOS transistor 221 is made wider than that of N channel MOS transistor 121. Therefore, drivability of N channel MOS transistor 221 is larger than that of N channel MOS transistor 121.

Meanwhile, P channel MOS transistor 222 has source electrode connected to output node 14, drain electrode connected to ground node 200, and gate electrode connected to drain and gate electrodes of P channel MOS transistor 103. The channel length of P channel MOS transistor 222 is made longer than that of P channel MOS transistor 122. Therefore, the threshold voltage of P channel MOS transistor 222 is larger than that of P channel MOS transistor 122.

The channel width of P channel MOS transistor 222 is made wider than that of P channel MOS transistor 122. Therefore, drivability of P channel MOS transistor 222 is made larger than that of P channel MOS transistor 122.

When the intermediate potential generating circuit is in a state of equilibrium, that is, when an intermediate potential (½) Vcc is generated at output node 14, a through current of about the sub threshold current flows through the first output stage 12. However, current does not flow at all in the second output stage 22.

Now, when the output potential V_(out) slightly deviates from the intermediate potential (½) Vcc, transistor 121 or 122 of the first output stage 12 is rendered conductive, and the output potential V_(out) returns to the intermediate potential (½) Vcc.

When the output potential V_(out) largely deviates from intermediate potential (½) Vcc, not only the first output stage 12 but also transistor 221 or 222 of the second output stage 22 is rendered conductive, and the output potential V_(out) returns to the intermediate potential (½) Vcc.

The drivability of transistors 221 and 222 of the second output stage 22 is larger than that of transistors 121 and 122 of the first output stage 12, and therefore even when the output potential V_(out) fluctuates significantly, it quickly returns to the original value.

The intermediate potential generating circuit is adapted such that the fluctuated output potential V_(out) is returned to the original intermediate potential (½) Vcc in accordance with the level of fluctuation of the output potential V_(out). Therefore, the output potential V_(out) does not oscillate near the intermediate potential (½) Vcc but quickly returns to the original intermediate potential (½) Vcc.

In Embodiment 3, the channel length and channel width of transistors 221 and 222 in the second output stage 22 are made longer than those of the first output stage 12. However, even when the length and width are the same as those in the first stage, the intermediate potential (½) Vcc is generated at output node 14. Though two output stages 12 and 22 are provided in Embodiment 3, three or more output stages may be provided.

[Embodiment 4]

FIG. 6 is a block diagram showing a whole structure of the intermediate potential generating circuit in accordance with Embodiment 4 of the present invention. Embodiment 4 is an application of Embodiment 3 to Embodiment 2.

Referring to FIG. 6, the intermediate potential generating circuit includes a control potential generating circuit 20, a reference potential generating stage 16, two output stages 18 and 24, and an output node. The threshold voltage of N channel MOS transistor 241 in the second output stage 24 is made larger than that of N channel MOS transistor 181 in the first output stage 18, and drivability of transistor 241 is made larger than that of transistor 181. The absolute value of the threshold voltage of P channel MOS transistor 242 in the second output stage 24 is made larger than that of P channel MOS transistor 182 of the first output stage 18, and drivability of transistor 242 is made larger than that of transistor 182.

In the intermediate potential generating circuit, by appropriately changing control potentials V_(con) 1 and V_(con) 2 generated by control potential generating circuit 20, the potential at node N3 can be set to the intermediate potential (½) Vcc, and therefore accurate intermediate potential (½) Vcc can be generated at output node 14.

Further, since first and second output stages 18 and 24 operate to return the output potential V_(out) to the intermediate potential (½) Vcc in accordance with the level of fluctuation of the output potential V_(out), a stable intermediate potential (½) Vcc can be generated constantly.

[Embodiment 5]

FIG. 7 is a cross section showing a structure of a transistor in an intermediate potential generating circuit in accordance with Embodiment 5 of the present invention.

In Embodiment 3 above, the threshold voltage of transistors 221 and 222 of the second output stage 22 is set higher than that of transistors 121 and 122 as the channel length is made longer than that of transistors 121 and 122 of the first output stage 12. However, the threshold voltage of the transistor may be changed by varying back bias.

Referring to FIG. 7, N channel MOS transistors 121 and 221 of Embodiment 5 are formed in P type wells 263 and 264 formed in a semiconductor substrate 261.

More specifically, N channel MOS transistor 121 includes source region 121S and drain region 121D formed in P type well 263 and a gate electrode 121G formed on the channel region with an insulating film therebetween. N channel MOS transistor 221 includes source region 221S and drain region 221D formed in P type well 264 and a gate electrode 221G.

In order to separate the P type wells 263 and 264 from p type semiconductor substrate 261, an N type buried layer 262 and three N type wells 265 to 267 are formed. On P type well 263, a contact region 268 is formed for applying a substrate potential V_(BB) 1. On P type well 264, a contact region 269 is formed for applying substrate potential V_(BB) 2.

Accordingly, substrate potentials V_(BB) 1 and V_(BB) 2 can be applied independent from each other to the back gates of two N channel MOS transistors 121 and 221. Therefore, by setting substrate potential V_(BB) 2 lower than substrate potential V_(BB) 1, the threshold voltage of transistor 221 can be made larger than that of transistor 121.

As is apparent from Embodiment 5, by applying different substrate potentials V_(BB) 1 and V_(BB) 2 to the transistors in the first and second output stages, the threshold voltages may be made different from each other. However, the structure of the transistor is simplified when the threshold voltage is changed by changing the channel length, than by applying different substrate potentials.

[Embodiment 6]

FIG. 8 is a circuit diagram showing the whole structure of an intermediate potential generating circuit in accordance with Embodiment 6 of the present invention. In Embodiment 6, reference potential generating stages 1 and 2 of the conventional intermediate potential generating circuit shown in FIG. 83 are provided in place of control potential generating circuit 20 and reference potential generating stage 16 of Embodiment 4 above.

Referring to FIG. 8, the intermediate potential generating circuit includes two reference potential generating stages 1 and 2, two output stages 18 and 24, and an output node 14.

The channel length of N channel MOS transistor 241 of the second output stage 24 is made longer than that of N channel MOS transistor 181 of the first output stage 18, and the channel length of P channel MOS transistor 242 is made longer than that of P channel MOS transistor 182.

Therefore, as in Embodiment 4 above, the first and second output stages 18 and 24 operate appropriately in accordance with the fluctuation level of output potential V_(out), and hence a stable intermediate potential (½) Vcc is constantly generated at output node 14.

[Embodiment 7]

FIG. 9 is a cross section showing a memory cell structure of a DRAM. Two memory cells are shown in FIG. 9.

Referring to FIG. 9, a capacitor C in memory cell MC is formed by a storage node STN and a cell plate CP. A transfer gate TG of memory cell MC is formed by a gate electrode, which is the word line WL, an N type source region, and an N type drain region. A bit line BL is connected to the N type source region.

Here, when the storage node STN is at the H level, the word line WL is at the L level and the bit line BL is at the L level, sub threshold current I₁ flows in the channel region below the word line WL, which may possibly destroy the data stored in capacitor C.

Therefore, there has been proposed a method in which the potential of the word line WL is made substantially lower than the bit line BL even when the word line WL and bit line BL both attain to the L level, by setting the L level of the bit line BL higher than that of the word line WL. This method is referred to as hierarchical power supply method.

More specifically, in such hierarchical power supply method illustrated by FIG. 10, the potential at word line WL swings between a boosted potential Vpp and an external ground potential extVss, while the potential at bit line BL swings between an internal power supply potential intVcc which is lower than the external power supply potential extVcc and an internal ground potential intVss which is higher than the external ground potential extVss. Therefore, even when the potential at storage node STN attains to the H level, the potential at word line WL attains to the L level and the potential at bit line BL attains to the L level, the potential at word line WL becomes substantially lower than the potential of bit line BL, and therefore leakage of the sub threshold current in the channel region can be suppressed. Therefore, destruction of data stored in capacitor C is not likely.

FIG. 11 is a circuit diagram showing the whole structure of the internal potential generating circuit in accordance with Embodiment 7 of the present invention.

In the above described hierarchical power supply method, the potential of bit line BL swings between internal power supply potential intVcc and internal ground potential intVss. Therefore, the bit line BL must be precharged to the intermediate potential (½) (intvcc−intVss) (hereinafter referred to as “(½) Vcc” for convenience), between internal power supply potential intvcc and internal ground potential Vss.

Intermediate potential generating circuit 36 shown in FIG. 11 generates the above described intermediate potential (½) Vcc. Referring to FIG. 11, intermediate potential generating circuit 36 includes, as Embodiment 1, a reference potential generating stage 10 and an output stage 12. Intermediate potential generating circuit 36 differs from Embodiment 1 in that reference potential generating stage 10 and output stage 12 are both connected between internal power supply node 500 to which internal power supply potential intVcc is applied, and a ground node 600 to which internal ground potential intVss is applied.

Internal power supply potential intVcc is generated by a voltage lowering circuit 32 based on an external power supply potential extVcc. Internal ground potential intVss is generated by a boosting circuit 34 based on an external ground potential extVss.

Voltage lowering circuit 32 and boosting circuit 34 constitute a power supply voltage converting circuit 30 for converting an external power supply voltage to an internal power supply voltage. Voltage lowering circuit 32 includes a differential amplifier 321 comparing a basic reference potential V_(refc) with internal power supply potential intVcc, and a P channel MOS transistor 322 operating in response to an output signal from the differential amplifier 321. By voltage lowering circuit 32, an internal power supply potential intVcc which is equal to the base reference potential V_(refc) is generated at internal power supply node 500.

Meanwhile, boosting circuit 34 includes a differential amplifier 341 comparing a base reference potential V_(refs) with internal ground potential intVss, and an N channel MOS transistor 342 operating in response to an output signal from differential amplifier 341. By boosting circuit 34, an internal ground potential intVss which is equal to the base reference potential V_(refs) is generated at internal ground node 600.

As is apparent from Embodiment 7, when an intermediate potential (½) Vcc between internal power supply potential intVcc and internal ground potential intVss is necessary, the intermediate potential generating circuit may be connected between internal power supply node 500 and internal ground node 600.

FIG. 12 is an illustration showing an example of the base reference potential generating circuit for generating two base reference potentials V_(refc) and V_(refs). In this example, the transistor 121 or 122 of FIG. 11 may have its drain electrode connected to a power supply node other than the internal power supply node 500 or internal ground node 600, for example, it may be connected to external power supply node 300 or external ground node 400. Transistor 121 and 122 may have their electrodes connected to power supply nodes other than nodes 500 and 600.

Referring to FIG. 12, the base reference potential generating circuit includes a constant current source 38 capable of supplying a constant reference current I_(const), and two resistance elements 40 and 42 connected in series. Resistance element 40 has a constant resistance value R1. Resistance value R2 of resistance element 42 may be appropriately changed.

FIG. 13 shows an example of constant current source 38 shown in FIG. 12.

Referring to FIG. 13, constant current source 38 includes a current mirror circuit consisting of two P channel MOS transistors 381 and 382, a current mirror circuit consisting of two N channel MOS transistors 383 and 384, a resistance element 385 connected between N channel MOS transistor 383 and an external ground node 400, and a P channel MOS transistor 386 for supplying a constant reference current I_(const).

Since the two current mirror circuits described above are cross coupled, reference current I_(ref) flowing from external power supply node 300 through transistors 381, 383 and resistance element 385 to external ground node 400 is constant and equal to reference current I_(ref) flowing from external power supply node 300 through transistors 3382 and 384 to external ground node 400. The magnitude of reference current I_(ref) is determined by the size of resistance element 385.

Further, since P channel MOS transistor 382 forms, together with P channel MOS transistor 381, a current mirror circuit, a constant reference current I_(const) which is equal to the reference current I_(ref) flows in transistor 386.

FIG. 14 is a graph showing the internal power supply potential, the internal ground potential and the intermediate potential when the base reference potential generating circuit shown in FIG. 12 is used.

For example, when the value of resistance element 42 shown in FIG. 12 is set to 0Ω, the base reference potential V_(refc) would be I_(const)×R1, and base reference potential V_(refs) would be 0V. Therefore, internal power supply potential intVcc becomes equal to the base reference potential V_(refc), and internal power supply intVss attains to 0V.

Thereafter, when the value of resistance element 42 is increased, the base reference potentials V_(refc) and V_(refs) both rise, while the voltage between the base reference potentials V_(refc) and V_(refs) is always kept constant. Therefore, the voltages of internal power supply potential intvcc and internal ground potential intVss are also kept constant.

Therefore, even when the value of resistance element 42 is changed, the intermediate potential generated at output node 14 is always intermediate between internal power supply potential intVcc and internal ground potential intVss.

[Embodiment 8]

FIG. 15 is a circuit diagram showing a structure of an intermediate potential generating circuit in accordance with Embodiment 8 of the present invention.

Referring to FIG. 15, the intermediate potential generating circuit includes a power supply voltage converting circuit 30, an intermediate potential generating portion 44 and an output node 14. The intermediate potential generating circuit differs from that of Embodiment 7 in that output stage 46 of intermediate potential generating portion 44 is connected between external power supply node 300 and external ground node 400.

More specifically, output stage 46 includes an N channel MOS transistor 461 and a P channel MOS transistor 462, and these transistors 461 and 462 are connected in series between external power supply node 300 and external ground node 400. Meanwhile, reference potential generating stage 10 of intermediate potential generating portion 44 is connected between internal power supply node 500 and internal ground node 600, as in Embodiment 7 above.

In the intermediate potential generating circuit, an intermediate potential (½) Vcc between internal power supply potential intvcc and internal ground potential intVss is generated at node N3 in reference potential generating stage 10. Therefore, a potential (½) Vcc+V_(tn) higher than the intermediate potential by the threshold voltage of N channel MOS transistor 102 is applied to the gate electrode of N channel MOS transistor 461 in the output stage 46, while a potential (½) Vcc−|V_(tp)| lower than the intermediate potential by the absolute value of the threshold voltage of P channel MOS transistor 103 is applied to the gate electrode of P channel MOS transistor 462. Therefore, though the output stage 46 is connected between external power supply node 300 and external ground node 400, an intermediate potential (½) Vcc between internal power supply potential intVcc and internal ground potential intVss is generated at output node 14.

[Embodiment 9]

FIG. 16 is a circuit diagram showing a structure of an intermediate potential generating circuit in accordance with Embodiment 9 of the present invention. Referring to FIG. 16, the intermediate potential generating circuit includes a power supply voltage converting circuit 30, an intermediate potential generating portion 45 and an output node 14. The intermediate potential generating circuit differs from that of Embodiment 8 in that an output stage 47 in intermediate potential generating portion 45 is connected between internal power supply node 500 and external ground node 400.

Specifically, output stage 47 includes an N channel MOS transistor 471 and a P channel MOS transistor 472, and these transistors 471 and 472 are connected in series between internal power supply node 500 and external ground node 400. Meanwhile, reference potential generating stage in intermediate potential generating portion 45 is connected between internal power supply node 500 and internal ground node 600, as in Embodiment 8 above.

According to the intermediate potential generating circuit, an intermediate potential (½) Vcc between internal power supply potential intVcc and internal ground potential intVss is generated at node N3. Therefore, a potential (½) Vcc+V_(tn) higher than the intermediate potential by the threshold voltage of N channel MOS transistor 102 is applied to the gate electrode of N channel MOS transistor 471 in output stage 47, while a potential (½) Vcc−|V_(tp)| lower than the intermediate potential by the absolute value of the threshold voltage of P channel MOS transistor 103 is applied to the gate electrode of P channel MOS transistor 472. Therefore, though output stage 47 is connected between internal power supply node 500 and internal ground node 400, an intermediate potential (½) Vcc between internal power supply potential intVcc and internal ground potential intVss is generated at output node 14.

In this manner, the N and P channel MOS transistors constituting the output stage has only to be source follower connected. In other words, any potential may be applied to the drain electrodes of N and P channel MOS transistors.

[Embodiment 10]

FIG. 17 is an illustration showing a structure of a base reference potential generating circuit in an intermediate potential generating circuit in accordance with Embodiment 10 of the present invention.

Referring to FIG. 17, the base reference potential generating circuit includes a first output node 50 at which base reference potential V_(refc) is generated, a second output node 52 at which base reference potential V_(refs) is generated, an output resistance element 40, a variable output resistance element 42, a constant current source 38 and a feedback circuit 48.

The base reference potential generating circuit is used in place of the base reference potential generating circuit shown in FIG. 12. The base reference potential generating circuit differs from that of FIG. 12 in that a feedback circuit 48 is newly provided.

In the base reference potential generating circuit, part I1 of base current I_(const) supplied from the constant current source 38 flows to resistance elements 40 and 42. Therefore, a constant base reference potential V_(refc) is generated at first output node 50, and a constant base reference potential V_(refs) is generated at second output node 52.

Remaining part I2 of reference current I_(const) flows to feedback circuit 48. Feedback circuit 48 detects the remaining current I2, and when the current I2 decreases, the circuit increases the reference current I_(const) supplied from constant current source 38, and if the current I2 increases, the circuit decreases the reference current I_(const) supplied from constant current source 38.

When current flows to a buffering capacitance element (not shown) connected to output node 50, for example, the current I2 flowing to feedback circuit 48 decreases. Feedback circuit 48 controls such that reference current I_(const) supplied from constant current source 38 increases, in response to the decrease in current I2.

Therefore, the current flowing to output resistance elements 40 and 42 does not decrease, and constant base reference potentials V_(refc) and V_(refs) are always generated at output nodes 50 and 52, respectively.

FIG. 18 is a schematic diagram showing the specific structure of the base reference potential generating circuit shown in FIG. 17.

Referring to FIG. 18, the base reference potential generating circuit includes a first current mirror circuit consisting of P channel MOS transistors 381 and 382, a second current mirror circuit consisting of N channel MOS transistors 383 and 384, an N channel MOS transistor 541 connected between second current mirror circuit and external power supply node 400, a P channel transistor 386 constituting, together with P channel MOS transistor 381, a current mirror circuit, a diode connected P channel MOS transistor 401 which corresponds to the aforementioned resistance element 40, a diode connected P channel MOS transistor 421 which corresponds to the aforementioned resistance element 42, and first and second output nodes 50 and 52.

P channel MOS transistor 386 has its drain electrode connected to drain electrode of N channel MOS transistor 541. N channel MOS transistor 541 has its gate electrode connected to second output node 52.

In the similar manner as described above, in the base reference potential generating circuit, when current flows to a buffering capacitance element connected to first output node 50, for example, current I2 flowing to N channel MOS transistor 541 decreases. N channel MOS transistor 541 functions as a resistance element, and a constant voltage is applied between the drain and source electrodes thereof. Therefore, the current flowing in transistor 541 is constant. Therefore, when current 12 decreases, reference current I_(ref) flowing through P channel MOS transistor 381 and N channel MOS transistor 383 increases. Since P channel MOS transistor 381 and P channel MOS transistor 386 constitute a current mirror circuit, a reference current I_(const) which is equal to reference current I_(ref) flows in P channel MOS transistor 386. Therefore, reference current I_(const) increases in response to the increase of the reference current I_(ref), and therefore the current I1 flowing to P channel MOS transistors 401 and 421 does not decrease. Accordingly, base reference potentials V_(refc) and V_(refs) generated at output nodes 50 and 52 thereof do not decrease.

In Embodiment 10, P channel MOS transistors 381 and 382 constituting the first current mirror circuit, N channel MOS transistors 383 and 384 constituting the second current mirror circuit, N channel MOS transistor 54 serving as a resistance element and P channel MOS transistor 386 provides a constant current source 38 as well as a feedback circuit 48.

[Embodiment 11]

FIG. 19 is a schematic diagram showing a whole structure of the base reference potential generating circuit in an intermediate potential generating circuit in accordance with Embodiment 11 of the present invention. The base reference potential generating circuit is used in place of the base reference potential generating circuit shown in FIG. 12.

Referring to FIG. 19, the base reference potential generating circuit includes a control potential generating circuit 54 for generating a prescribed control potential V_(con), a P channel MOS transistor 386 receiving at its gate electrode the control potential V_(con), a first output node 50, a second output node 52, a P channel MOS transistor 402 connected between first and second output nodes 50 and 52, and a P channel MOS transistor 422 connected between second output node 52 and an external ground node 400.

P channel MOS transistor 402 has its gate electrode connected to external ground node 400, and serves as an output resistance element. P channel MOS transistor 422 has its gate electrode connected to external ground node 400, and serves as an output resistance element.

The control potential generating circuit 54 includes two P channel MOS transistors 381 and 382 constituting a first current mirror circuit, two N channel MOS transistors 383 and 384 constituting a second current mirror circuit, a resistance element 542 connected between P channel MOS transistor 381 and N channel MOS transistor 383, and a resistance element 543 connected between N channel MOS transistor 383 and external ground node 400. Namely, the control potential generating circuit 54 differs from that of FIG. 13 in that a resistance element 542 is newly provided.

By control potential generating circuit 54, the potential at the gate electrode of P channel MOS transistor 381 is not directly applied as the control potential to the gate electrode of P channel MOS transistor 386, and a potential lower than the potential at the gate electrode by the voltage drop across resistance element 542 is generated at control node 545, and the potential generated at control node 545 is applied to the gate electrode of P channel MOS transistor 386 as control potential V_(con).

Therefore, in the base reference potential generating circuit, the reference current I_(const) flowing through P channel MOS transistor 386 is changed by appropriately changing the value of resistance element 542, and thus base reference potentials V_(refc) and V_(refs) generated at output nodes 50 and 52 are changed.

Further, in Embodiment 11, when resistance element 542 has positive temperature coefficient and resistance element 543 has negative temperature coefficient, the temperature dependency of resistance element 542 is offset by the temperature dependency of resistance element 543, and therefore control potential V_(con) generated at control node 545 is not dependent on the change in temperature.

When the difference between the absolute value of temperature coefficient of resistance element 542 and the absolute value of temperature coefficient of resistance element 543 is made sufficiently large, the control potential V_(con) would be dependent on temperature change. Therefore, a desired control potential V_(con) can be generated by appropriately adjusting the difference.

Metal, polysilicon to which much metal is introduced or the like is used as the resistance element having positive temperature coefficient. Polycrystalline silicon, polycrystalline silicon to which small amount of metal is introduced, or a semiconductor such as an N type well is used as a resistance element having negative temperature coefficient.

Resistance element 543 may have positive temperature coefficient and resistance element 542 may have negative temperature coefficient.

[Embodiment 12]

FIG. 20 is a circuit diagram showing the whole structure of a base reference potential generating circuit in an intermediate potential generating circuit in accordance with Embodiment 12 of the present invention. The base reference potential generating circuit may be used also in place of the base reference potential generating circuit shown in FIG. 12.

Referring to FIG. 20, the base reference potential generating circuit includes a control potential generating circuit 54, a P channel MOS transistor 386, a first output node 50, a second output node 52, a P channel MOS transistor 403 functioning as an output resistance element, and an N channel MOS transistor 423 functioning as an output resistance element.

The base reference potential generating circuit differs from that of Embodiment 11 above in that the P channel MOS transistor connected between the first and second output nodes 50 and 52 is diode connected, and that the gate electrode of N channel MOS transistor 423 connected between second output node 52 and external power supply node 400 is connected to the first output node 50.

Therefore, in the state of equilibrium at which a stable base reference potential V_(refc) is generated at first output node 50, N channel MOS transistor 423 simply serves as resistance element, as a constant base reference potential V_(refc) is applied to the gate electrode thereof.

However, when base reference potential V_(refc) generated at first output node 50 decreases, the conduction resistance of N channel MOS transistor 423 becomes larger, and the voltage drop across the transistor 423 increases. Therefore, even when the base reference potential V_(refc) lowers, it is quickly returned to the prescribed based reference potential V_(refc). Similarly, even when base reference potential V_(refc) increases, it is quickly returned to the prescribed base reference potential V_(refc).

In this manner, in the base reference potential generating circuit in accordance with Embodiment 12, since the potential generated at first output node 50 is fed back to N channel MOS transistor 423 serving as the output resistance element, even when the potential generated at first output node 50 fluctuates, it quickly returns to the original value. Therefore, the base reference potential generating circuit can always generate stable base reference potentials V_(refc) and V_(refs).

[Embodiment 13]

FIG. 21 is a circuit diagram showing the whole structure of the base reference potential generating circuit in an intermediate potential generating circuit in accordance with Embodiment 13 of the present invention. The base reference potential generating circuit may be used instead of the base reference potential generating circuit shown in FIG. 12.

Referring to FIG. 21, the base reference potential generating circuit includes a control potential generating circuit 55, a P channel MOS transistor 386, P channel MOS transistors 402 and 422, and first and second output nodes 50 and 52.

The base reference potential generating circuit differs from Embodiment 11 above in that a P channel MOS transistor 544 is provided in place of resistance element 542, in control potential generating circuit 55.

More specifically, the P channel MOS transistor 544 is connected between P channel MOS transistor 381 and N channel MOS transistor 383, and has its gate electrode connected to external ground node 400. Therefore, the P channel MOS transistor 544 serves as a resistance element.

Now, if external power supply potential extVcc rises, the voltage between the source and gate electrodes of P channel MOS transistor 544 increases, and therefore conduction resistance of transistor 544 decreases. Accordingly, voltage drop across P channel MOS transistor 544 decreases, and control potential V_(con), generated at control node 545 is increased. Accordingly, a constant voltage is always applied to the source and gate electrodes of P channel MOS transistor 386, and hence a constant reference current I_(const) always flows in transistor 386. Therefore, in the base reference potential generating circuit in accordance with Embodiment 13, even when external power supply potential extVcc fluctuates, stable base reference potentials V_(refc) and V_(refs) are constantly generated.

[Embodiment 14]

FIG. 22 is a circuit diagram showing the whole structure of a base reference potential generating circuit in accordance with Embodiment 14 of the present invention. The base reference potential generating circuit is for supplying base reference potential V_(refs) to differential amplifier 341 in Embodiment 7, 8 or 9 above.

Referring to FIG. 22, the base reference potential generating circuit includes a control potential generating circuit 56 for generating a prescribed reference potential V_(con), an N channel MOS transistor 603 receiving at its gate the control potential V_(con), two P channel MOS transistors 601 and 602 constituting a current mirror circuit, a resistance element 424 connected between P channel MOS transistor 602 and external ground node 400, and an output node 52 at which base reference potential V_(refs) is generated. Here, the transistor 602 has its channel length made longer than that of transistor 601.

In control potential generating circuit 56, since two current mirror circuits are cross coupled, a constant reference current I_(ref) determined by resistance element 385 flows. Since N channel MOS transistors 384 and 603 constitute a current mirror circuit, a reference current I_(ref) which is equal to the reference current I_(ref) in control potential generating circuit 56 also flows through N channel MOS transistor 603.

Further, since P channel MOS transistors 601 and 602 constitute a current mirror circuit, a reference current I_(ref) which is equal to the reference current I_(ref) flowing through P channel MOS transistor 601 flows through P channel MOS transistor 602. Therefore, a constant reference current I_(ref) flows through resistance element 424, and hence a constant base reference potential V_(ref) is generated at output node 52.

FIG. 23 is a graph showing general drain current characteristic of an MOS transistor. In this graph, the ordinate represents the drain current, and the abscissa represents source.drain voltage. Drain current characteristics for different gate potentials are shown in the graph. As represented by the solid line in FIG. 23, when the channel length is long, the drain current becomes constant regardless of the source.drain voltage in the saturation region. However, as represented by chain dotted line in FIG. 23, when the channel length is short, the drain current slightly increases as the source.drain voltage increases, in the saturation region.

In the base reference potential generating circuit in accordance with Embodiment 14, a base reference potential V_(refs) which is equal to the internal ground potential Vss is generated at output node 52. Therefore, a high voltage is applied between source.drain of transistor 602. If the channel length of transistor 602 is equal to that of transistor 601, the reference current I_(ref) flowing through transistor 602 would be larger than the reference current I_(ref) flowing through transistor 601. However, since the channel length of transistor 602 is made longer than that of transistor 601, a reference current I_(ref) which is equal to the reference current I_(ref) flowing through transistor 601 flows through transistor 602, though a high voltage is applied between source.drain of transistor 602. Therefore, a constant reference current I_(ref) flows through resistance element 424, and the constant base reference potential V_(refs) is generated at output node 52.

[Embodiment 15]

FIG. 24 shows the whole structure of the base reference potential generating circuit in accordance with Embodiment 15 of the present invention.

Referring to FIG. 24, the base reference potential generating circuit includes a control potential generating circuit 57 for generating a prescribed control potential V_(con), an N channel MOS transistor 603 receiving at its gate electrode the control potential V_(con), two P channel MOS transistors 601 and 602 providing a current mirror circuit structure, a resistance element 424, and an output node 52.

The base reference potential generating circuit differs from that of Embodiment 14 in that a resistance element 622 is connected between P channel MOS transistor 382 and N channel MOS transistor 384. Therefore, a potential higher than the gate potential of N channel MOS transistor 384 by the voltage drop across resistance element 622 is generated as control potential V_(con) at control node 571 of control potential generating circuit 57. Therefore, a control potential V_(con) which is higher than the gate potential of N channel MOS transistor 384 is applied to the gate electrode of N channel MOS transistor 603, and hence reference current I_(ref) 2 which is larger than reference current I_(ref) flowing through transistor 384 flows therethrough.

In the base reference potential generating circuit in accordance with Embodiment 15, the control potential V_(con) and hence the base reference potential V_(refs) generated at output node 52 can be appropriately changed by changing the value of resistance element 622 appropriately.

In control potential generating circuit 57, when resistance element 621 having positive temperature coefficient and resistance element 622 having negative temperature coefficient are used, the temperature dependency of resistance elements 621 and 622 can be offset by each other as in Embodiment 12, and therefore the base reference potential V_(refs) generated at output node 52 will not be dependent on the change in temperature.

As already described with reference to Embodiment 12 above, it is possible to provide the base reference potential V_(refs) generated at output node 52 with desired temperature dependency.

Meanwhile, a material having positive temperature coefficient may be used for resistance element 622 while a material having negative temperature coefficient may be used for resistance element 621.

[Embodiment 16]

FIG. 25 is a circuit diagram showing the whole structure of a base reference potential generating circuit in accordance with Embodiment 16 of the present invention.

Referring to FIG. 25, the base reference potential generating circuit includes a control potential generating circuit 58 generating a prescribed control potential V_(con), an N channel MOS transistor 603, two P channel MOS transistors 601 and 602 constituting a current mirror circuit, a resistance element 424, and an output node 52.

The base reference potential generating circuit differs from Embodiment 15 above in that an N channel MOS transistor 623 is provided in place of resistance element 622. The gate electrode of N channel MOS transistor 623 is connected to external power supply node 300. Therefore, the N channel MOS transistor 623 serves as a resistance element, as the external power supply potential extVcc is applied to its gate electrode.

In the base reference potential generating circuit, as in Embodiment 13 above, even when external power supply potential extVcc fluctuates, a constant reference current I_(ref) 2 always flows through resistance element 424, and therefore a constant base reference potential V_(refs) is always generated at output node 52.

[Embodiment 17]

FIG. 26 is a circuit diagram showing the whole structure of a base reference potential generating circuit in accordance with Embodiment 17 of the present invention.

The base reference potential generating circuit differs from Embodiment 15 above in that a P channel MOS transistor 425 is provided in place of resistance element 424. A negative substrate potential V_(BB) is applied to the gate electrode of P channel MOS transistor 425.

Therefore, P channel MOS transistor 425 serves as a resistance element. Further, since substrate potential V_(BB) is applied to the gate electrode, base reference potential V_(refs) fluctuates when substrate potential V_(BB) fluctuates.

As is apparent from Embodiment 17, a P channel MOS transistor may be used as the resistance element.

[Embodiment 18]

FIG. 27 is a circuit diagram showing the whole structure of a base reference potential generating circuit in accordance with Embodiment 18 of the present invention.

The base reference potential generating circuit differs from Embodiment 15 above in that an N channel MOS transistor 426 is provided in place of resistance element 424. And external power supply potential extVcc is applied to the gate electrode of N channel MOS transistor 426.

Therefore, N channel MOS transistor 426 serves as a resistance element. In the base reference potential generating circuit, if external power supply potential extVcc fluctuates, the conduction resistance of N channel MOS transistor 426 also fluctuates, and therefore, base reference potential V_(refs) is generated at output node 52 fluctuates together with external power supply potential extVcc.

[Embodiment 19]

FIG. 28 is a circuit diagram showing a structure of a base reference potential generating circuit in accordance with Embodiment 19 of the present invention.

The base reference potential generating circuit differs from Embodiment 17 above in that a substrate potential detecting circuit 64 is newly provided. The substrate potential detecting circuit 64 includes two P channel MOS transistors 642 and 643 constituting a current mirror circuit, an N channel MOS transistor 641 connected between P channel MOS transistors 602 and 425, two N channel MOS transistors 644 and 645 constituting, together with transistor 641, a current mirror circuit, a diode connected P channel MOS transistor 646, and a resistance element 647.

In substrate potential detecting circuit 64, a potential higher than the base reference potential V_(refs) by the threshold voltage of N channel MOS transistor 641 is applied to the gate electrodes of N channel MOS transistors 644 and 645.

Therefore, when the substrate potential V_(BB) detected at one end of resistance element 647 is not sufficiently low, current does not flow through N channel MOS transistor 645, and hence control signal EN is at the H level. A substrate potential supplying circuit (not shown) is activated in response to the H level control signal EN, and supplies a prescribed substrate potential V_(BB) at the semiconductor substrate on which the DRAM is formed.

Thereafter, when the substrate potential V_(BB) becomes sufficiently low, current flows through P channel MOS transistor 646 and through resistance element 647. When the source potential of P channel MOS transistor 646 becomes lower than the base reference potential V_(refs), control signal EN attains to the L level. The substrate potential supplying circuit is inactivated in response to the L level control signal EN.

The voltage drop across P channel MOS transistor 646 and resistance element 647 can be appropriately set.

[Embodiment 20]

FIG. 29 is a circuit diagram showing a structure of a reference potential generating circuit in accordance with Embodiment 20 of the present invention.

The reference potential generating circuit differs from Embodiment 19 above in that a hysterisis circuit 66 is newly provided.

In Embodiment 20, when the substrate potential V_(BB) is not sufficiently low, an H level control signal ENhys is generated. The H level control signal ENhys is applied to the gate electrode of P channel MOS transistor 661 through in inverter 662, and hence the transistor 661 is conductive.

When the substrate potential V_(BB) becomes sufficiently low and control signal ENhys attains to the L level, P channel MOS transistor 661 is rendered non-conductive. Therefore, current flowing through transistors 645 and 646 decreases. Therefore, even when the substrate potential V_(BB) rises and not sufficiently low, control signal ENhys does not immediately attain to the H level. In other words, hysterisis circuit 66 provides hysterisis with control signal ENhys. Therefore, there is not a chattering generated in control signal ENhys.

[Embodiment 21]

FIG. 30 is a circuit diagram showing a structure of a base reference potential generating circuit in accordance with Embodiment 21 of the present invention. The base reference potential generating circuit differs from Embodiment 20 above in that the source electrode of N channel MOS transistor 644 in substrate potential detecting circuit 64 is connected not to the output node 52 at which base reference potential V_(refs) is generated but to an internal ground node 600. In the reference potential generating circuit, even when substrate potential detecting circuit 64 operates, the base reference potential V_(refs) does not fluctuate.

[Embodiment 22]

FIG. 31 is a circuit diagram showing a main structure of a base reference potential generating circuit in accordance with Embodiment 22 of the present invention.

Referring to FIG. 31, in addition to the components of Embodiments 15, 17 and 18, a start up circuit 68 is provided in this reference potential generating circuit.

Start up circuit 68 includes a P channel MOS transistor 681 receiving at its gate electrode a substrate potential V_(BB) or the ground potential, a diode connected P channel MOS transistor 682, and an N channel MOS transistor 683 connected between the drain electrode of transistor 681 and external ground node 400. The drain electrode of P channel MOS transistor 682 and the gate electrode of N channel MOS transistor 683 are connected to the gate electrodes of N channel MOS transistors 383 and 384 in control potential generating circuit 57.

According to Embodiment 22, when the power is turned on, initially, current flows through transistors 681 and 682 from external power supply node 300 to the gate electrodes of two N channel MOS transistors 383 and 384 constituting a current mirror circuit. Consequently, current flows quickly after power on in control potential generating circuit 57. Therefore, a prescribed control potential is generated quickly.

When the gate potentials of transistors 383 and 384 rise to a prescribed value, transistor 683 is rendered conductive, and hence the current flowing from external power supply node 300 through transistor 681 further flows through transistor 683 to external ground node 400. Further, since there is provided a diode connected P channel MOS transistor 682, current does not flow in reverse direction from control potential generating circuit 57 toward the start up circuit 68.

[Embodiment 23]

FIG. 32 is a circuit diagram showing the whole structure of an intermediate potential generating circuit in accordance with Embodiment 23 of the present invention.

Referring to FIG. 32, Embodiment 23 is a combination of Embodiments 7, 13, 16 and 22 above.

The present invention may be implemented by appropriately combining the embodiment described above, other than the combination just mentioned above.

[Embodiment 24]

FIG. 33 is a circuit diagram showing a structure of reference potential generating circuit in accordance with Embodiment 24 of the present invention.

Like Embodiment 23, this Embodiment 24 is also a combination of several embodiments described above.

Referring to FIG. 33, the reference potential generating circuit includes a constant current generator 74, a current difference generator 72, a voltage generator 76, a substrate potential detecting circuit 70, a voltage lowering circuit 32 and a boosting circuit 34.

Constant current generator 74 includes start up circuit 68 shown in FIG. 31, and a control potential generating circuit 78. Control potential generating circuit 78 is a combination of control potential generating circuit 55 shown in FIG. 21 and control potential generating circuit 58 shown in FIG. 25 in which a P channel MOS transistor 544 is connected between P channel MOS transistor 381 and N channel MOS transistor 383, and an N channel MOS transistor 623 is connected between P channel MOS transistor 382 and an N channel MOS transistor 384.

Therefore, a control potential V_(con) 1 not dependent on the change in external power supply potential extVcc is applied to the gate electrodes of two N channel MOS transistors 644 and 645 in substrate potential detecting circuit 70. Further, a control potential V_(con) 2 not dependent on the change in external power supply potential extVcc is applied to the gate electrode of P channel MOS transistor 386 in voltage generator 76.

Therefore, transistor 386 supplies reference current I_(ref) to transistors 401 and 428 in response to control signal V_(con) 2. Accordingly, in voltage generator 76, base reference potentials V_(refc) and V_(refs) are generated in response to the reference current I_(ref). The base reference potential V_(refs) is determined by the conduction resistance of P channel MOS transistor 428 receiving at its gate electrode the substrate potential V_(BB). The base reference potential V_(refc) is determined based on the conduction resistance and threshold voltage of the diode connected P channel MOS transistor 401 as well as the base reference potential V_(refs).

Meanwhile, in substrate potential detecting circuit 70, internal ground potential intVss is applied to the source electrode of transistor 644 to which gate electrode the control potential V_(con) 1 is applied, and substrate potential V_(BB) is applied to the source electrode of transistor 701 to which gate electrode the base reference potential V_(refc) is applied.

Therefore, when the substrate potential V_(BB) becomes sufficiently low, the current flowing through transistor 645 becomes larger than the current flowing through transistor 644, and hence control signal EN attains to the L level. Therefore, a substrate potential supplying circuit (not shown) is inactivated in response to the L level control signal EN. Meanwhile, if the substrate potential V_(BB) is not sufficiently low, control signal EN attain to the H level, and the substrate potential supplying circuit is activated.

Current difference generator 72 includes two P channel MOS transistors 721 and 722 constituting a current mirror circuit, an N channel MOS transistor 723 having the identical structure as a transfer gate in a memory cell, and an N channel MOS transistor 724 constituting, together with transistor 723, a current mirror circuit.

Control potential V_(con) 2 is applied to the gate electrodes of transistors 721 and 722, and therefore reference current I_(ref) flows through transistors 721 and 722 in response to the control potential V_(con) 2.

Here, when the peripheral temperature increases, the threshold voltages of transistors 723 and 724 decrease. In current difference generator 72, the threshold voltage of transistor 723 is set to be smaller than that of transistor 724 when the peripheral temperature rises.

Therefore, when the peripheral temperature increases, the current I_(q) flowing through transistor 724 decreases, and current I_(p) flowing from current difference generator 72 to voltage generator 76 increases. When current I_(p) increases, the base reference potential V_(refs) increases. Therefore, as the peripheral temperature increases, internal ground potential intvss increases.

Generally, the sub threshold current flowing through transfer gate in a memory 7ell tends to be increased as the temperature rises. However, in Embodiment 24, internal ground node intVss rises as the temperature rises, and hence substantially lower potential is applied to the gate electrode of the transfer gate as the temperature rises. Therefore, sub threshold current does not increase even when the temperature rises.

When the substrate potential V_(BB) increases and not sufficiently low any more, the threshold voltage of transistor 723 becomes smaller, and therefore current I_(p) flowing from current difference generator 72 to voltage generator 76 increases. When current I_(p) increases, base reference potential V_(refs) increases, and internal ground potential intVss also increases. Therefore, in this case also, substantially lower potential is applied to the gate electrode of the transfer gate in the memory cell as the temperature rises, and hence sub threshold current does not increase even when the temperature rises.

[Embodiment 25]

FIG. 34 is a circuit diagram showing a structure of an internal potential detecting circuit in accordance with Embodiment 25 of the present invention.

FIG. 35 is a circuit diagram showing a specific structure of the internal potential detecting circuit shown in FIG. 34.

Referring to FIGS. 34 and 35, the internal potential detecting circuit includes an output node 801, a constant current source 802 supplying a constant reference current I_(ref) 1, a detecting node 804 to which a low potential VL to be detected is applied, and a resistance element 803 connected between output node 801 and detecting node 804.

Constant current source 802 is formed by a P channel MOS transistor 805, for example, as shown in FIG. 35. A constant reference potential V_(ref) 1 is applied to the gate electrode of transistor 805. Therefore, a constant reference current I_(ref) 1 flows in transistor 805.

Meanwhile, resistance element 803 is formed by an N channel MOS transistor 806, for example, as shown in FIG. 35. A constant reference potential V_(ref) 2 is applied to the gate electrode of transistor 806. Therefore, transistor 806 has a constant drain resistance, and serves as a resistor.

As a low internal potential VL, a substrate potential V_(BB), for example, is applied to detecting node 804. When the applied substrate potential V_(BB) is sufficiently low, that is, when it is sufficiently lower than the ground potential, the current for comparison I_(cmp) flowing through transistor 806 is larger than reference current I_(ref) 1, and therefore output node 801 is discharged. Accordingly, an enable signal GE at the L (logic low) level is generated.

Meanwhile, when the applies substrate potential V_(BB) is shallow, namely, when it is not sufficiently lower than the ground potential, the current for comparison I_(cmp) is smaller than reference current I_(ref) 1, and therefore output node 801 is charged. Therefore, an enable signal GE at H level is generated.

The generated enable signal GE is supplied to the substrate potential generating circuit (not shown). When the enable signal GE is at the L level, the substrate potential generating circuit is inactivated. When enable signal GE is at the H level, the substrate potential generating circuit is activated, generating substrate potential V_(BB).

Therefore, by the internal potential detecting circuit, whether or not the substrate potential V_(BB) has attained the prescribed level is determined. Further, since constant reference current I_(ref) 1 is supplied to the output node 801 even when power supply potential Vcc fluctuates, the detecting level of the internal potential detecting circuit does not fluctuate. Therefore, when the substrate potential generating circuit is controlled by using the internal potential detecting circuit, a constant substrate potential V_(BB) not dependent on the fluctuation of power supply potential Vcc can be obtained.

[Embodiment 26]

FIG. 36 is an illustration showing a structure of the internal potential detecting circuit in accordance with Embodiment 26 of the present invention. FIG. 37 is a circuit diagram showing specific structure of the internal potential detecting circuit shown in FIG. 36. The internal potential detecting circuit in accordance with Embodiment 26 is for detecting a high internal potential VH, unlike the internal potential detecting circuit of FIG. 34.

Referring to FIGS. 36 and 37, in the internal potential detecting circuit, a constant current source 802 is connected between an output node 801 and ground node 200. Further, a resistance element 803 is connected between a detection node 804 and an output node 801. A high internal potential VH (for example, boosted potential V_(pp)) is applied to detection node 804.

Constant current source 802 is formed by an N channel MOS transistor 807, for example, as shown in FIG. 37. A constant reference potential V_(ref) 1 is applied to the gate electrode of transistor 807. Therefore, a constant reference current I_(ref) 1 flows through transistor 807.

Meanwhile, resistance element 803 is formed by a P channel MOS transistor 808, for example, as shown in FIG. 37. A constant reference potential V_(ref) 2 is applied to the gate electrode of transistor 808. Therefore, transistor 808 has a constant drain resistance, and serves as a resistor.

In the internal potential detecting circuit, when boosted potential V_(pp) is sufficiently high, the current for comparison I_(cmp) flowing through transistor 808 is larger than the reference current I_(ref) 1, and hence output node 801 is charged. Therefore, an H level enable signal /GE is generated.

Meanwhile, when the boosted potential V_(pp) is not sufficiently high, that is, when it is low, the current for comparison I_(cmp) is smaller than the reference current I_(ref) 1, and hence output node 801 is discharged. Therefore, an L level enable signal /GE is generated.

The generated enable signal /GE is supplied to a boosted potential generating circuit. The boosted potential generating circuit is inactivated when the enable signal /GE is at the H level. Meanwhile, the boosted potential generating circuit is activated when the enable signal GE is at the L level, and generates a boosted potential V_(pp).

Therefore, by the internal potential detecting circuit, whether or not the boosted potential V_(pp) has attained a prescribed detection level is determined. Even when the ground potential Vss fluctuates, the detection level does not fluctuate together with the ground potential Vss, since a constant reference current I_(ref) 1 is supplied from output node 801 to ground node 200.

Therefore, by controlling the boosted potential generating circuit by using the internal potential detecting circuit, a constant boosted potential V_(pp) not dependent on the fluctuation of the ground potential Vss can be obtained.

[Embodiment 27]

FIG. 38 is an illustration showing a structure of an internal potential detecting circuit in accordance with Embodiment 27 of the present invention. Referring to FIG. 38, the internal potential detecting circuit includes, in addition to the components shown in FIG. 34, an N channel MOS transistor 809. The transistor 809 is connected between output node 801 and resistance element 803. A constant reference potential V_(ref) 3 is applied to the gate electrode of transistor 809. In the internal potential detecting circuit, when the substrate potential V_(BB) applied to the detection node 804 is shallow, the voltage Vsg across the source and gate of transistor 809 is smaller than the threshold voltage, and therefore transistor 809 is not conducted. Accordingly, current for comparison I_(cmp) does not flow at all, and output node 801 is charged by reference current I_(ref) 1. Accordingly, an H level enable signal GE is generated.

Meanwhile, when the substrate potential V_(BB) becomes lower and the source potential of transistor 809 becomes lower than the reference potential V_(ref) 3 by the threshold voltage, transistor 809 is rendered conductive, and current for comparison I_(cmp) flows. When the substrate potential V_(BB) is sufficiently low, the current for comparison I_(cmp) becomes larger than the reference current I_(ref) 1, and hence output node 801 is discharged by the current for comparison I_(cmp), and an L level enable signal GE is generated.

Therefore, the detection level of the internal potential detecting circuit is determined by the reference potential V_(ref) 3. Therefore, even when the power supply potential Vcc fluctuates, the detection level does not fluctuate. Further, the voltage across resistance element 803 of Embodiment 27 is smaller than the voltage across the resistance element 803 in Embodiment 25 above. Therefore, when the current for comparison I_(cmp) of Embodiment 27 is the same as that in Embodiment 25, it is possible to make smaller the value of resistance element 803. Since it is generally difficult to form a resistance element having high value, Embodiment 27 can be implemented easier than Embodiment 25 above.

[Embodiment 28]

FIG. 39 is an illustration showing the structure of an internal potential detecting circuit in accordance with Embodiment 28 of the present invention.

Referring to FIG. 39, the internal potential detecting circuit includes a P channel MOS transistor 810 in addition to the components shown in FIG. 36. Transistor 810 is connected between resistance element 803 and output node 801. A constant reference potential V_(ref) 3 is applied to the gate electrode of transistor 810.

When boosted potential V_(pp) is low, transistor 810 is rendered non-conductive, and current for comparison I_(cmp) does not flow at all. Therefore, output node 801 is discharged by reference current I_(ref) 1, and an L level enable signal GE is generated.

Meanwhile, when boosted potential V_(pp) increases and the source potential of transistor 810 becomes higher than reference potential V_(ref) 3 by its threshold voltage, transistor 810 is rendered conductive, and current for comparison I_(cmp) flows. When boosted potential V_(pp) is sufficiently high, the current for comparison I_(cmp) becomes larger than the reference current I_(ref) 1, and hence output node 801 is charged by the current for comparison I_(cmp). Thus, an H level enable signal /GE is generated.

The voltage across the resistance element 803 in Embodiment 28 is smaller than the voltage across resistance element 803 of Embodiment 26 above. Therefore, the value of resistance element 803 can be decreased. Therefore, Embodiment 28 can be more easily implemented than Embodiment 26 above.

[Embodiment 29]

FIG. 40 is an illustration showing a structure of an internal potential detecting circuit in accordance with Embodiment 29 of the present invention.

Referring to FIG. 40, the internal potential detecting circuit includes an output node 801, a constant current source 802 supplying a constant reference current I_(ref) 1 from output node 801 to ground node 200, a detection node 804 to which a low internal potential VL to be detected is applied, a resistance element 803 connected to detection node 804, and a current mirror circuit 811 for supplying current for comparison I_(cmp) which is equal to the detection current I_(det) flowing through resistance element 803 to output node 801. Current mirror circuit 811 includes P channel MOS transistors 812 and 813. Transistor 812 has its gate electrode and source electrode connected to each other. Transistor 812 has its gate electrode connected to the gate electrode of transistor 813. Constant current source 802 is formed by an N channel MOS transistor having a gate electrode receiving a constant reference potential, as constant current source 802 of FIG. 37. Similar to resistance element 803 of FIG. 35, resistance element 803 is formed by an N channel MOS transistor receiving at its gate a constant reference potential.

In the internal potential detecting circuit, a reference potential V_(BB), for example, is applied as low internal potential VL to detection node 804. When substrate potential V_(BB) is sufficiently deep, a detection current I_(det) flows through resistance element 803. Current mirror circuit 811 supplies a current for comparison I_(cmp) which is equal to the detection current I_(det) to output node 801. When substrate potential V_(BB) is sufficiently deep, current for comparison I_(cmp) is larger than reference current I_(ref) 1, and therefore output node 801 is charged by reference current I_(cmp). Therefore, an H level enable signal /GE is generated.

Meanwhile, when the substrate potential V_(BB) is shallow, reference current I_(ref) 1 is larger than the current for comparison I_(cmp), and therefore output node 801 is discharged by the reference current I_(ref) 1. Therefore, an L level enable signal GE is generated. When the substrate potential V_(BB) is very shallow, the voltage Vsg across the source gate of transistor 812 becomes smaller than the threshold voltage, and hence transistor 812 is rendered non-conductive. Consequently, detection current I_(det) does not flow at all, and hence power consumption can be reduced as compared with the embodiments above not using the current mirror.

[Embodiment 30]

FIG. 41 is an illustration showing a structure of an internal potential detecting circuit in accordance with Embodiment 30 of the present invention. Different from the internal potential detecting circuit shown in FIG. 40, the internal potential detecting circuit is for detecting a relatively high internal potential VH such as the boosted potential Vpp. Referring to FIG. 41, the internal potential detecting circuit includes an output node 801, a constant current source 802 supplying a constant reference current I_(ref) 1 from power supply node 100 to output node 801, a detection node 804 to which internal potential VH is applied, a resistance element 803 connected to detection node 804, and a current mirror circuit 814 for supplying a current for comparison I_(cmp) which is equal to the detection current I_(det) flowing through resistance element 803 from output node 801 to ground node 200. Current mirror circuit 814 includes N channel MOS transistors 815 and 816. Transistor 815 has its gate electrode and drain electrode connected to each other. Transistor 815 has its gate electrode connected to the gate electrode of transistor 816.

In the internal potential detecting circuit, when the internal potential V_(pp) applied to detection node 804 is sufficiently high, a detection current I_(det) flows through resistance element 803. Current mirror circuit 814 supplies current for comparison I_(cmp) which is equal to detection current I_(det) from output node 801 to ground node 200. When boosted potential V_(pp) is sufficiently high, current for comparison I_(cmp) is larger than reference current I_(ref) 1, and hence output node 801 is discharged by the current for comparison I_(cmp). Therefore, an L level enable signal GE is generated.

Meanwhile, when boosted potential V_(pp) is low, reference current I_(ref) 1 becomes larger than current for comparison I_(cmp), and hence output node 801 is charged by reference current I_(ref). Therefore, an H level enable signal GE is generated. When boosted potential V_(pp) is very low, the voltage Vsg across source-gate of transistor 815 becomes smaller than the threshold voltage, and transistor 815 is rendered non-conductive. Consequently, detection current I_(det) does not flow at all, and hence power consumption of internal potential detecting circuit in accordance with Embodiment 30 can be reduced as compared with the Embodiments above not using current mirror circuit.

[Embodiment 31]

FIG. 42 is an illustration showing i structure of an internal potential detecting circuit in accordance with Embodiment 31 of the present invention.

Referring to FIG. 42, in the internal potential detecting circuit, constant current source 802 and resistance element 803 are provided at reverse positions as compared with FIG. 40. In other words, constant current source 802 and current mirror circuit 811 of Embodiment 31 correspond to constant current source 802 of FIG. 34.

In internal potential detecting circuit, a constant reference current I_(ref) 1 flows through transistor 812. Current mirror circuit 811 supplies a reference current I_(ref) 1 which is equal to the reference current I_(ref) 1 to output node 801. Therefore, when the substrate potential V_(BB) applied to detection node 804 is sufficiently deep, current for comparison I_(cmp) becomes larger than the reference current I_(ref) 1, and hence an L level enable signal GE is generated. Meanwhile, when the substrate potential V_(BB) is shallow, reference current I_(ref) 1 becomes larger than current for comparison I_(cmp), and hence an H level enable signal GE is generated.

[Embodiment 32]

FIG. 43 is an illustration showing a structure of an internal potential detecting circuit in accordance with Embodiment 32 of the present invention. Referring to FIG. 43, in the internal potential detecting circuit, constant current source 802 and resistance element 803 are provided at positions reverse to those of FIG. 41. In other words, constant current source 802 and current mirror circuit 814 of Embodiment 32 correspond to constant current source 802 of FIG. 36.

In the internal potential detecting circuit, a constant reference current I_(ref) 1 flows through transistor 815. Current mirror circuit 814 supplies a reference current I_(ref) 1 which is equal to the reference current I_(ref) 1 from output node 801 to ground node 200. Therefore, when the boosted potential V_(pp) applied to detection node 804 is sufficiently high, the current for comparison I_(cmp) becomes larger than reference current I_(ref) 1, and hence an H level enable signal /GE is generated. Meanwhile, when the boosted potential V_(pp) is low, reference current I_(ref) 1 becomes larger than the current for comparison I_(cmp), and hence an L level enable signal /GE is generated.

[Embodiment 33]

FIG. 44 is an illustration showing a structure of an internal potential detecting circuit in accordance with Embodiment 33 of the present invention. Referring to FIG. 44, the internal potential detecting circuit includes, in addition to the components of FIG. 40, an N channel MOS transistor 809. Transistor 809 is connected between transistor 812 and resistance element 803. A constant reference voltage V_(ref) 3 is applied to the gate electrode of transistor 809. Constant current source 802 is formed by an N channel MOS transistor 807 as shown in FIG. 45. The aforementioned reference voltage V_(ref) 3 is applied to the gate electrode of transistor 807. Resistance element 803 is formed by an N channel MOS transistor 806, as shown in FIG. 45. The aforementioned reference voltage V_(ref) 3 is applied to the gate electrode of transistor 806. Therefore, transistor 807 serves as a constant current source, and transistor 806 serves as a resistor. The internal potential detecting circuit is for determining whether or not the substrate potential V_(BB) has attained a prescribed level, and therefore it will be referred to as substrate potential detecting circuit in the following.

In the substrate potential detecting circuit, when the substrate potential V_(BB) applied to detection node 804 is low, transistors 809 and 812 are both rendered non-conductive, and therefore detection current I_(det), does not flow at all in transistor 806. Therefore, current for comparison I_(cmp) is not supplied at all from power supply node 100 through transistor 813 to output node 801, and hence output node 801 is discharged by reference current I_(ref) 1 flowing through transistor 807. Therefore, an L level enable signal /GE is generated. The substrate potential generating circuit is activated in response to the L level enable signal /GE.

When the substrate potential generating circuit is activated, the substrate potential V_(BB) lowers gradually. Consequently, when the voltage Vsg across source·gate of transistor 812 becomes larger than the threshold voltage thereof, transistor 812 is rendered conductive. When the voltage Vsg across source·gate of transistor 809 becomes larger than its threshold voltage, transistor 809 is rendered conductive. Therefore, as the substrate potential V_(BB) becomes lower, the detection current I_(det) increases, and current for comparison I_(cmp) also increases. The current for comparison I_(cmp) becomes equal to reference current I_(ref) 1, when substrate potential V_(BB) satisfies the relation defined by the equation (2) below:

V _(BB) =V _(ref) 3−V _(tn) −V _(on)  (2)

where V_(tn) represents threshold voltage of transistor 809. V_(on) represents the voltage across source·drain of transistor 806 when it is conductive. Therefore, the voltage V_(on) can be represented by the equation (3) below, where drain resistance of transistor 806 when it is conductive is represented as Rd:

V _(on) =V _(det) ×Rd  (3)

When substrate potential V_(BB) is sufficiently deep, current for comparison I_(cmp) larger than reference current I_(ref) 1 flows to output node 801. Consequently, output node 801 is charged, and an H level enable signal /GE is generated. The substrate potential generating circuit is inactivated in response to the H level enable signal GE.

Now, the threshold voltage V_(tp) of transistor 809 becomes smaller as operational temperature increases. The drain resistance Rd of transistor 806 increases as operational temperature increases. Therefore, assuming that the detection current I_(det) is constant, the voltage V_(on) across source·drain of transistor 806 increases as the operational temperature increases. Since voltages V_(tp) and V_(on) both change approximately linearly with respect to the operational temperature, the fluctuation of voltages V_(tn) and V_(on) with operational temperature can be offset. Therefore, the detection level of the internal potential detecting circuit is always constant, regardless of the operational temperature.

According to Embodiment 33, since the detection level is determined by the reference voltage Vref³, the detection level does not fluctuate even when power supply potential Vcc fluctuates. Therefore, when the substrate potential generating circuit is controlled by using the substrate potential detecting circuit, a stable substrate potential V_(BB) not dependent on the fluctuation of power supply potential Vcc can be obtained.

Further, since transistors 806 and 809 are connected in series, a stable detection level not dependent on the fluctuation of operational temperature can be obtained. Further, when the substrate potential V_(BB) is not sufficiently low, transistor 812 is rendered non-conductive, and hence current consumption can be reduced.

[Embodiment 34]

FIG. 46 is a schematic diagram showing a structure of a substrate potential detecting circuit in accordance with Embodiment 34 of the present invention.

Referring to FIG. 46, the substrate potential detecting circuit includes a substrate potential detecting portion 80, a differential amplifier 82, and inverters 83 and 84. Substrate potential detecting portion 80 includes, in addition to the components shown in FIG. 45, a P channel MOS transistor 817. Transistor 817 is connected parallel to transistor 813. An output from inverter 84 is applied to the gate electrode of transistor 817.

Differential amplifier 82 includes P channel MOS transistors 821 to 823 and N channel MOS transistors 824 and 825. Transistor 821 has its source electrode connected to power supply node 100, and receives at its gate electrode, a constant reference potential V_(ref) 4. Therefore, transistor 821 serves as a constant current source. Transistors 822 and 823 have their source electrodes both connected to the drain electrode of transistor 821. Transistor 822 has its gate electrode connected to the gate electrode of transistor 812 in substrate potential detecting portion 80. Transistor 823 has its gate electrode connected to an output node NY in substrate potential detecting portion 80. Transistor 824 is connected between transistor 822 and ground node 200, while transistor 825 is connected between transistor 823 and ground node 200. Transistor 824 has its gate electrode and drain electrode connected to each other. Transistor 824 has its gate electrode further connected to the gate electrode of transistor 825. Therefore, transistors 824 and 825 constitute a current mirror circuit. The potential at output node NZ of differential amplifier 82 is applied to inverter 83, and enable signal /GE is output from inverter 83.

FIG. 47 shows the whole structure of the substrate potentials detecting circuit including, in addition to the structure of FIG. 46, a reference potential generating circuit 58 for generating the aforementioned reference potentials V_(ref) 3 and V_(ref) 4. The reference potential generating circuit 58 shown in FIG. 47 is the one shown in the Embodiment above, and it generates reference potentials V_(ref) 3 and V_(ref) 4 which are constant regardless of the fluctuation in power supply potential Vcc and in operational temperature.

FIG. 48 shows the manner of change of the potential at various nodes in the substrate potential detecting circuit shown in FIGS. 46 and 47 when the substrate potential V_(BB) gradually lowers and then gradually rises. As shown in FIG. 48(a), when the substrate potential V_(BB) is shallow, or more specifically, when the substrate potential V_(BB) is higher than the detection level L1, transistor 812 in substrate potential detecting portion 80 is non-conductive, and hence the potential at the source node NX is approximately equal to the supply potential Vcc as shown in FIG. 48(b). Further, since transistor 813 is also non-conductive, current for comparison I_(cmp) does not flow at all, and therefore the potential at output node NY is at the ground potential Vss.

When the substrate potential V_(BB) gradually lowers as shown in FIG. 48(a) and the voltage Vsg between source·gate of transistor 812 reaches the threshold voltage, transistor 812 is rendered conductive, and the potential at node NX attains to the potential which is lower than the power supply potential Vcc by the threshold voltage of transistor 812. Meanwhile, as the substrate potential V_(BB) lowers, current for comparison I_(cmp) starts to flow in transistor 813, and hence the pote ntial at node NY gradually increases.

The potentials at nodes NX and NY are compared by differential amplifier 82. While the potential at node NX is higher than the potential at node NY, the potential at output node NZ in differential amplifier 82 is at the power supply potential Vcc, that is, H (logic high) level as shown in FIG. 48(c). Therefore, an L level enable signal /GE is provided from inverter 83.

Further, when the potential at node NY attains higher than the potential at node NX, the potential at output node NZ in differential amplifier 82 changes from the H level to the L level, as shown in FIG. 48(c). When the potential at output node NZ attains to the L level, an H level enable signal /GE is output from inverter 83.

When the enable signal /GE is at the H level, an L level signal is applied from inverter 84 to the gate electrode of transistor 817. Therefore, transistor 817 is rendered conductive, and hence additional current I_(add) is supplied from power supply node 100 to output node NY.

Thereafter, when substrate potential V_(BB) gradually increases as shown in FIG. 48(a), current for comparison I_(cmp) flowing through transistor 813 decreases, and the potential at output node NY lowers gradually. Since there is additional current I_(add) flowing through transistor 817, when the reference current I_(ref) 1 becomes larger than the sum of current for comparison I_(cmp) and additional current I_(add), the potential at output node NY attains to the L level. When the potential at output node NY becomes lower than the potential at node NX, the potential at output node NZ in differential amplifier 82 changes from the L level to the H level, and hence enable signal /GE changes from the H level to the L level.

In this manner, when the substrate potential V_(BB) attains to the detection level L2 which is higher than the detection level L1, the enable signal /GE attains to the L level. Namely, the detection level of the substrate potential detecting circuit has hysterisis.

When transistor 817 and inverter 84 are not provided, the detection level when the substrate potential V_(BB) lowers and the detection level when the substrate potential V_(BB) rises are the same with each other. Therefore, there would be a chattering in the enable signal when the substrate potential V_(BB) is near the detection level. However, since transistor 817 and inverter 84 are provided in the substrate potential detecting circuit of Embodiment 34 so as to provide hysterisis to the detection level, such chattering is not generated in the enable signal /GE.

Further, the reference current I_(ref) 1 flowing through transistor 807 is preferably set to be lower than several μA. Therefore, when it takes long time for charging/discharging the parasitic capacitance of output node NY, the potential at output node NY is amplified by the differential amplifier 82, since differential amplifier 82 is provided in the internal potential detecting circuit in accordance with Embodiment 34. Therefore, the enable signal /GE can rise and fall quickly.

FIG. 49 is a graph showing relation between detection levels L1 and L2 and the power supply potential Vcc. The abscissa represents the power supply potential Vcc, and the ordinate represents the detection level. As is apparent from the graph of FIG. 49, the detection levels L1 and L2 are approximately constant regardless of the power supply potential Vcc. This is because the detection levels L1 and L2 are determined not based on the power supply potential Vcc but on a constant reference potential V_(ref) 3 .

[Embodiment 35]

FIG. 50 is an illustration showing a structure of a boosted potential detecting circuit in accordance with Embodiment 35 of the present invention. Referring to FIG. 50, the boosted potential detecting circuit includes, in addition to the structure of FIG. 41, a P channel MOS transistor 810. Transistor 810 is connected between resistance element 803 and transistor 815. Transistor 810 receives at its gate a constant reference potential V_(ref) 3. Namely, the boosted potential detecting circuit is a modification of the substrate potential detecting circuit shown in FIG. 44, for detecting the boosted potential V_(pp). Therefore, the boosted potential detecting circuit operates approximately in the same manner as the substrate potential detecting circuit shown in FIG. 44.

FIG. 51 is a circuit diagram showing specific structure of the substrate potential detecting circuit shown in FIG. 50, which corresponds to FIG. 45. As shown in FIG. 51, resistance element 803 is formed by a P channel MOS transistor 808 which receives at its gate electrode the reference potential V_(ref) 3. Constant current source 802 is formed by a P channel MOS transistor 805 which receives at its gate electrode the reference potential V_(ref) 4. Therefore, transistor 808 serves as a resistor, and transistor 805 serves as a constant current source.

In the boosted potential detecting circuit, when the boosted potential V_(pp) applied to the detection node 804 is not sufficiently high, the reference current I_(ref) 1 flowing through transistor 805 is larger than the current for comparison I_(cmp) flowing through transistor 816, and hence output node 801 is charged and an H level enable signal GE is generated. In response to the H level enable signal GE, a boosted potential generating circuit is activated.

Meanwhile, when the boosted potential V_(pp) is sufficiently high, the current for comparison I_(cmp) is larger than the reference current I_(ref) 1, and hence output node 801 is discharged and an L level enable signal GE is generated. In response to the L level enable signal GE, the boosted potential generating circuit is inactivated.

According to Embodiment 35, since the detection level is determined based not on the power supply potential Vcc but on the reference potential V_(ref) 3, even when the power supply potential Vcc fluctuates, the detection level of the boosted potential detecting circuit does not fluctuate. Further, since the drain resistance of transistor 808 increases as the operational temperature rises and the threshold voltage of transistor 810 becomes smaller as the operational temperature rises, the temperature dependency of voltage drop across transistor 808 and temperature dependency of voltage drop across transistor 810 are offset by each other. Therefore, a stable detection level not dependent on the operational temperature can be obtained. Further, when the boosted potential V_(pp) is very low, transistor 815 is rendered non-conductive, and hence detection current I_(det) and current for comparison I_(cmp) do not flow at all, whereby current consumption car be reduced.

[Embodiment 36]

FIG. 52 is a circuit diagram showing a structure of a boosted potential detecting circuit in accordanc e with Embodiment 36 of the present invention. Referring to FIG. 52, the boosted potential detecting circuit includes a boosted potential detecting portion 81, a differential amplifier 85 for amplifying an output from boosted potential detecting portion 81, and inverters 83 and 84. In addition to the structure of FIG. 51, boosted potential detecting portion 81 includes an N channel MOS transistor 818. Transistor 818 is connected parallel to transistor 816, and receives at its gate electrode, an output from inverter 84. The boosted potential detecting circuit shown in FIG. 52 is a modification of the substrate potential detecting circuit shown in FIG. 46 for detecting the boosted potential V_(pp). Therefore, the boosted potential detecting circuit operates approximately in the same manner as the substrate potential detecting circuit shown in FIG. 46.

FIG. 53 corresponds to FIG. 47, and it includes reference potential generating circuits 58 and 86 added to the boosted potential detecting circuit shown in FIG. 52. Referring to FIGS. 52 and 53, the differential amplifying circuit 85 includes P channel MOS transistors 851 and 852, and N channel MOS transistors 853 to 855. Transistors 851 and 852 ,constitute a current mirror circuit. Transistor 853 has its gate connected to the gate electrode of transistor 815 in boosted potential detecting portion 81. Transistor 854 has its gate electrode connected to an output node NY in the boosted potential detecting portion 81. Since a constant reference potential V_(ref) 5 generated by reference potential generating circuit 58 is applied to the gate electrode of transistor 855, transistor 855 serves as a constant current source.

Referring to FIG. 53, reference potential generating circuit 86 includes P channel MOS transistors 861 to 863. Since a constant reference potential V_(ref) 4 generated by reference potential generating circuit 58 is applied to the gate electrode of transistor 861, transistor 861 serves as a constant current source. Transistors 862 and 863 are connected in series, and ground potential Vss is applied to the gate electrodes of these. Therefore, transistors 862 and 863 as a whole function as a resistor. Since a constant current is supplied from transistor 861 to transistors 862 and 863, a constant reference potential V_(ref) 3 which is not dependent on the power supply potential Vcc is generated at the source node of transistor 862. The reference potential V_(ref) 3 is applied to the gate electrodes of transistors 808 and 810 in the boosted potential detecting portion 81. The reference potential V_(ref) 4 generated by reference potential generating circuit 58 may be applied to the gate electrodes of transistors 808 and 810. However, by providing the reference potential generating circuit 86 in this manner, the reference potential V_(ref) 3 can be appropriately changed by changing the size of transistors 862 and 863.

FIG. 54 shows the manner of change of potentials at various nodes in the boosted potential detecting circuit shown in FIGS. 52 and 53, when the boosted potential V_(pp) gradually rises and then gradually lowers. When the boosted potential V_(pp) is not sufficiently high as shown in FIG. 54(a), transistor 815 in boosted potential detecting portion 81 is rendered conductive, and therefore the potential at node NX would be approximately equal to ground potential Vss.

When the boosted potential V_(pp) rises and transistor 815 is rendered conductive, the potential at node NX rises to be higher than the ground potential Vss by the threshold voltage of transistor 815. Further, when the potential at node NY becomes lower than the potential at node NX, the potential at output node NZ in differential amplifying circuit 85 changes from the L level to the H level as shown in FIG. 54(c). Therefore, the enable signal GE changes from the H level to the L level as shown in FIG. 54(d).

While the enable signal GE is at the L level, an H level signal is applied to the gate electrode of transistor 818 in boosted potential detecting portion 81, and therefore, in addition to current for comparison I_(cmp) flowing through transistor 816, additional current I_(add) flows through transistor 818.

Thereafter, when the boosted potential gradually lowers as shown in FIG. 54(a), current for comparison I_(cmp) gradually lowers, and therefore the potential at output node NY gradually rises. When the potential at output node NY becomes higher than the potential at node NX, the potential at output node NZ in differential amplifying circuit 85 changes from the H level to the L level as shown in FIG. 54(c). Therefore, the enable signal GE changes from the L level to the H level as shown in FIG. 54(d). Here, even when the boosted potential V_(pp) lowers and current for comparison I_(cmp) lowers to be smaller than reference current I_(ref) 1, the potential at output node NY does not attain to the H level, since there is the additional current I_(add). The potential at output node NY attains to the H level when the sum of current for comparison I_(cmp) and additional current I_(add) becomes smaller than the reference current I_(ref) 1. Therefore, there is hysterisis in the detection level of the boosted potential detecting circuit, as shown in FIG. 54(a). More specifically, the detection level L2 at which enable signal GE changes from the L level to the H level as the boosted potential V_(pp) lowers, is lower than the detection level L1 at which enable signal GE changes from the H level to the L level, as the boosted potential V_(pp) rises. Therefore, chattering is not generated in the enable signal GE.

[Embodiment 37]

FIG. 55 is a circuit diagram showing the whole structure of a substrate potential detecting circuit in accordance with Embodiment 37 of the present invention. Referring to FIG. 55, in substrate potential detecting portion 87 of Embodiment 37, a P channel MOS transistor 871 is provided in place of transistor 806 of substrate potential detecting portion 80 shown in FIG. 47. Transistor 871 is connected between source electrode of transistor 809 and ground node 200, and it has its gate electrode connected to detection node 804. Namely, transistor 871 is connected in source follower manner, to transistor 809.

In substrate potential detecting portion 87, when the substrate potential V_(BB) applied to detection node 804 is not sufficiently low, detection current I_(det) hardly flows through transistor 871, and therefore current for comparison I_(cmp) becomes lower than the reference current I_(ref) 1. Therefore, the potential at output node NY attains to the L level. Meanwhile, when the substrate portion V_(BB) is sufficiently low, sufficient detection current I_(det) flows through transistor 871, and therefore current for comparison I_(cmp) becomes larger than reference current I_(ref) 1. Therefore, the potential at output node NY attains to the H level.

According to Embodiment 37, since transistor 871 is connected in the source follower manner, input impedance becomes higher. Therefore, current hardly flows from the substrate potential generating circuit to the substrate potential detecting circuit.

[Embodiment 38]

FIG. 56 is a circuit diagram showing the whole structure of a substrate potential detecting circuit in accordance with Embodiment 38 of the present invention.

Referring to FIG. 56, substrate potential detecting portion 88 in Embodiment 38 includes, in addition to the structure of substrate potential detecting portion 87 shown in FIG. 55, a P channel MOS transistor 881. Transistor 881 is connected between the source electrode of transistor 809 and the source electrode of transistor 871, and has its gate electrode connected to detection node 804.

The internal potential detecting portion 88 operates approximately in the same manner as internal potential detecting portion 87 shown in FIG. 55. However, since transistor 881 is provided in internal potential detecting portion 88, the temperature dependency of voltage drop caused by drain resistance of transistor 881 is offset by he temperature dependency of the threshold voltage of transistor 809. Therefore, detection level of substrate potential detecting portion 88 does not fluctuates, even if operational temperature fluctuates.

[Embodiment 39]

FIG. 57 is a circuit diagram showing a structure of a boosted potential detecting circuit in accordance with Embodiment 39 of the present invention. Referring to FIG. 57, in Embodiment 39, a P channel current mirror circuit 882 is provided in place of N channel current mirror circuit 814. Further, an N channel MOS transistor 885 is connected between transistor 810 and ground node 200, and an N channel MOS transistor 886 is connected between output node 801 and ground node 200.

Current mirror circuit 882 includes a diode connected P channel MOS transistor 883, and a P channel MOS transistor 884 having its gate electrode connected to the gate electrode of transistor 883. A constant reference potential V_(ref) 6 is applied to the gate electrodes of transistors 885 and 886. Therefore, transistors 885 and 886 both serve as constant current source. A constant reference current I_(ref) 1 flows through transistor 886.

In the boosted potential detecting circuit, when the boosted potential V_(pp) applied to detection node 804 is not sufficiently high, detection current I_(det) hardly flows through transistor 808. Current mirror circuit 882 supplies a current for comparison I_(cmp) which is approximately equal to the detection current I_(det) to output node 801. Since current for comparison I_(cmp) is smaller than reference current I_(ref) 1, output node 801 is discharged, and hence an L level enable signal /GE is generated. In response to the L level enable signal /GE, the boosted potential generating circuit is activated.

Meanwhile, when the boosted potential V_(pp) is sufficiently high, sufficient detection current I_(det) flows through transistor 808, and current for comparison I_(cmp) larger than reference current I_(ref) 1 flows. Therefore, output node 801 is charged, and an H level enable signal /GE is generated. In response to the H level enable signal /GE, the boosted potential generating circuit is inactivated.

As is apparent from Embodiment 39, current mirror circuit may be provided not on the side of the ground node of output node 801, but on the side of detection node 804.

[Embodiment 40]

FIG. 58 is an illustration showing a structure of an internal potential detecting circuit in accordance with Embodiment 40 of the present invention. Referring to FIG. 58, in Embodiment 40, a variable resistance element 887 is provided in place of resistance element 803 shown in FIG. 34. The variable resistance element 887 is formed, for example, by a plurality of fixed resistance elements connected parallel to each other. In each fixed resistance element, fuse links are connected in series, and by blowing off any of the fuse links by means of laser beam, the resistance value can be appropriately changed. Switching elements may be connected in series with the fixed resistance elements, instead of the fuse links. In that case, the resistance value can be appropriately changed by switching on/off the switching elements in response to a prescribed control signal, similar to the blowing of the fuse links. Further, by controlling on/off of the switching elements by using a program element, on/off of the switching elements can be controlled arbitrarily even after the step of assembly. These methods may be similarly applied to other embodiment also.

In embodiment 40, since the value of resistance element 887 can be appropriately changed, the detection level of the internal potential detecting circuit can be set to a desired value.

[Embodiment 41]

FIG. 59 is an illustration showing a structure of an internal potential detecting circuit in accordance with Embodiment 41 of the present invention. Referring to FIG. 59, in Embodiment 41, a variable resistance element 887 is provided instead of resistance element 803 shown in FIG. 36. The value of variable resistance element 887 can be appropriately changed as in Embodiment 40 above. Therefore, by appropriately changing the value of variable resistance element 887, the detection level of the internal potential detecting circuit can be set to a desired value.

[Embodiment 42]

FIG. 60 is an illustration showing a whole structure of a substrate potential detecting circuit in accordance with Embodiment 42 of the present invention. Referring to FIG. 60, the substrate potential detecting circuit includes, in addition to the substrate potential detecting portion 80 shown in FIG. 45, a reference potential generating circuit 89. Reference potential generating circuit 89 includes a variable resistance element 890, and a constant current source 888 for supplying a constant reference current I_(ref) 2 to the resistance element 890. The value of variable resistance element 890 can be appropriately changed, as the variable resistance element 887 shown in FIGS. 58 and 59. Therefore, the reference potential V_(ref) 3 generated at output node 889 of reference potential generating circuit 89 can be arbitrarily changed. Since the reference potential V_(ref) 3 is applied to the gate electrodes of transistors 806 and 809 in internal potential detecting portion 80, the detection level of substrate potential detecting portion 80 can be changed to a desired value.

[Embodiment 43]

FIG. 61 is an illustration showing a structure of a boosted potential detecting circuit in accordance with Embodiment 43 of the present invention. Referring to FIG. 61, the boosted potential detecting circuit includes, in addition to the boosted potential detecting portion 81 shown in FIG. 51, a reference potential generating circuit 90 for generating a reference potential V_(ref) 3.

Reference potential generating circuit 90 includes P channel MOS transistors 891 and 892 connected in series, and a constant current source 888 for supplying a constant reference current I_(ref) 2 to the transistors 891 and 892. Transistor 891 serves as a resistor, of which resistance value can be appropriately changed. Such transistor 891 may be formed by a plurality of P channel MOS transistors connected in parallel, and the resistance value thereof can be appropriately changed by blowing fuse links connected in series with each transistor by a laser beam. Transistor 892 is diode connected, and therefore the source potential of transistor 892 is set higher than the ground potential Vss by the threshold voltage of transistor 892.

According to Embodiment 43, by tuning the drain resistance of transistor 891, the reference potential V_(ref) 3 generated at output node 889 can be arbitrarily changed. Since reference potential V_(ref) 3 is applied to the gate electrodes of transistors 808 and 810 in boosted potential detecting portion 81, the detection level of boosted potential detection portion 81 can be changed to a desired value.

Instead of transistors 891 and 892 shown in FIG. 61, the variable resistance 890 shown in FIG. 60 may be used. In place of variable resistance element 890 shown in FIG. 60, transistors 891 and 892 shown in FIG. 61 may be used. Further, by changing the number of diode connected transistors such as transistor 892, the reference potential V_(ref) 3 may be changed.

[Embodiment 44]

FIG. 62 is a circuit diagram showing the whole structure of a substrate potential detecting circuit in accordance with Embodiment 44 of the present invention. Referring to FIG. 62, substrate potential generating circuit 91 in Embodiment 44 includes, in addition to the structure of reference potential generating circuit 89 shown in FIG. 60, a resistance element 893 and an N channel MOS transistor 894. Resistance element 893 is connected between output node 889 and variable resistance element 890. Transistor 894 is connected parallel to resistance element 893. A control signal /CNT is applied to the gate electrode of transistor 894.

Since an H level control signal CNT is applied in a normal mode, transistor 894 is rendered conductive. Therefore, substrate potential detecting circuit operates in the similar manner as that shown in FIG. 60.

Meanwhile, when an L level control signal /CNT is applied, transistor 894 is rendered non-conductive, and therefore resistance element 893 is added to variable resistance element 890. Consequently, reference potential V_(ref) 3 rises, and detection level of internal potential detecting portion 80 becomes higher than in the normal mode. Accordingly, as the substrate potential generating circuit is controlled by such a substrate potential detecting circuit, substrate potential V_(BB) which is shallower than in the normal mode is generated. When control signal /CNT returns to the H level, the substrate potential V_(BB) generated by the substrate potential generating circuit returns to the original deep level.

[Embodiment 45]

FIG. 63 is a circuit diagram showing the whole structure of a boosted potential detecting circuit in accordance with Embodiment 45 of the present invention. Referring to FIG. 63, reference potential generating circuit 92 of Embodiment 45 includes, in addition to the structure of reference potential generating circuit 90 shown in FIG. 61, P channel MOS transistors 896 and 897. Transistor 896 is connected between output node 889 and transistor 891. Transistor 896 receives, at its gate electrode, the ground node potential Vss. Therefore, transistor 896 serves as a resistor. Transistor 897 is connected parallel to transistor 896. Control signal /CNT is applied to the gate electrode of transistor 897.

Since the H level control signal /CNT is applied in the normal mode, transistor 897 is kept non-conductive. Therefore, transistors 891 and 892 as well as transistor 896 serve as a resistor.

Meanwhile, when the L level control signal /CNT is applied, transistor 897 is rendered conductive, and therefore the source and the drain of transistor 896 is short-circuited. Accordingly, transistor 896 is substantially eliminated, and hence reference potential V_(ref) 3 becomes lower than in the normal mode. Since the reference potential V_(ref) 3 is applied to the gate electrodes of transistors 808 and 810 in boosted potential detecting portion 81, detection level of boosted potential detecting portion 81 becomes lower than in the normal mode. Therefore, when the boosted potential generating circuit is controlled by such a boosted potential detecting circuit, the boosted potential V_(pp) generated by the boosted potential generating circuit also become lower. When control signal /CNT returns from the L level to the H level, the detection level of boosted potential detecting portion 81 returns to the original higher level. Therefore, the boosted potential V_(pp) generated by the boosted potential generating circuit also attains to the original high value.

[Embodiment 46]

FIG. 64 is a circuit diagram showing a whole structure of an internal potential detecting circuit in accordance with Embodiment 46 of the present invention. Referring to FIG. 64, the internal potential detecting circuit includes substrate potential detecting portion 80 shown in FIG. 45, boosted potential detecting portion 81 shown in FIG. 51, and reference potential generating circuit 58 shown in FIG. 47. The reference potential V_(ref) 3 generated by reference potential generating circuit 58 is applied to the gate electrodes of transistors 806, 807 and 809 of substrate potential detecting portion 80, as well as to the gate electrodes of transistors 808 and 810 of boosted potential detecting portion 81.

According to Embodiment 46, since internal potential detecting portion 80 and boosted potential detecting portion 81 share one reference potential generating circuit 58, the number of reference potential generating circuits can be reduced as compared with the example in which one reference potential generating circuit is provided for each of the detecting portions 80 and 81. Consequently, layout area of the whole internal potential detecting circuit can be reduced.

[Embodiment 47]

FIG. 65 is a block diagram showing part of a DRAM in accordance with Embodiment 47 of the present invention. Referring to FIG. 65, the DRAM includes an internal circuit 93 including a word line driving circuit and so on, an internal potential generating circuit 94 for generating a boosted potential V_(pp) and supplying the same to internal circuit 93, a voltage lowering circuit 32 for generating an internal power supply potential intVcc to be supplied to internal circuit 93 by lowering an external power supply potential extVcc, a reference potential generator 98 for generating a reference potential V_(refc) for the voltage lowering circuit 32, and boosted potential detecting circuit 81 shown in FIG. 51.

Reference potential generator 98 is connected between an external power supply node 300 and an external ground node 400, and generates a prescribed reference potential V_(refc). Voltage lowering circuit 32 lowers the external power supply potential extVcc to an internal power supply potential intVcc which is equal to the reference potential V_(refc). Internal circuit 93 is connected between an internal power supply node 500 and an internal ground node 600 and performs prescribed operations. The boosted potential V_(pp) generated by boosted potential generator 94 is supplied to internal circuitry 93 as well as to a detection node 804 of boosted potential detecting circuit 81. In internal circuit 93, the boosted potential V_(pp) is used, for example, as a potential for driving a word line. The reference potential V_(pp) generated by reference potential generator 98 is applied to the gate electrodes of transistors 808 and 810 in boosted potential detecting circuit 81. Therefore, the detection level of boosted potential generating circuit 81 is determined by reference potential V_(refc). The enable signal GE from boosted potential detecting circuit 81 is supplied to the boosted potential generator 94. When the boosted potential V_(pp) supplied to detection node 804 is lower than the detection level, an H level enable signal GE is generated, and in response, the boosted potential generator 94 is activated. When the boosted potential V_(pp) attains the detection level, the enable signal GE changes from the H level to the L level, and the boosted potential generator 94 is inactivated.

In Embodiment 47, a P channel MOS transistor 900 is connected between external power supply node 300 and an output node of reference potential generator 98. A burn in signal /BIN is applied to the gate electrode of transistor 900. Since the burn in signal /BIN is at the H level in the normal mode, transistor 900 is kept non-conductive. Therefore, an internal power supply potential intVcc which is equal to the reference potential V_(refc) generated by reference potential generator 98 is generated.

Meanwhile, in the burn in mode, an L level burn in signal /BIN is applied to the gate electrode of transistor 900. Here, burn in mode refers to a mode for acceleration test of internal circuit 93, in which a power supply voltage higher than usual is applied to the internal circuit 93. Accordingly, when the L level burn in signal /BIN is applied, transistor 900 is rendered conductive, and reference potential V_(refc) is pulled to the external power supply potential extVcc. Since voltage lowering circuit 32 refers to the reference potential V_(refc) which is equal to the external power supply potential extVcc, an internal power supply potential intVcc which is equal to the external power supply potential extVcc is generated. Accordingly, the external power supply potential extVcc is supplied to the internal circuit 93.

FIG. 66 is a graph showing the reference potential V_(refc) and detection level of boosted potential detecting circuit 81 when external power supply potential extVcc rises from 0V to 7V. In the graph of FIG. 66, the detection level represented by the solid line is the detection level when the boosted potential V_(pp) lowers, while the detection level represented by the dotted line is the detection level when the boosted potential V_(pp) rises.

When an external power supply potential extVcc in the range of from 2.5 to 4.0V is applied, reference potential generator 98 generates a constant reference potential V_(refc) (2.5V in this example). When the supplied external power supply potential extVcc is lower than 2.5V, reference potential generator 98 generates a reference potential V_(refc) which is equal to the supplied external power supply potential extVcc, since it is incapable of generating a reference potential V_(refc) which is higher than the supplied external power supply potential. Further, if the supplied external power supply potential extVcc is higher than 4V, reference potential generator 98 generates a reference potential V_(refc) which is lower than the supplied external power supply potential extVcc by a prescribed voltage. Therefore, as shown in FIG. 66, while the external power supply potential extVcc rises from 0V to 2.5V, reference potential V_(refc) rises along with the rise of the external power supply potential extVcc. In the normal mode, while the external power supply potential extVcc rises from 2.5V to 4V, reference potential V_(refc) is kept constant. Further, when external power supply potential extVcc exceeds 4V, reference potential V_(refc) rises again, while keeping a prescribed space from the supplied external power supply potential extVcc. Such a reference potential generator 98 is disclosed, for example, in Japanese Patent Laying-Open No. 4-263193.

Meanwhile, in the burn in mode, since an L level burn in signal /BIN is applied to the gate electrode of transistor 900, reference potential V_(refc) becomes equal to the external power supply potential extVcc. Therefore, the reference potential V_(refc) in the burn in mode rises along with the rise of external power supply potential extVcc in the burn in mode, as shown in FIG. 66.

Since the detection level of boosted potential detecting circuit 81 is determined based on the reference potential V_(refc), the detection level becomes higher than the reference potential V_(refc) by a prescribed voltage. More specifically, as shown in FIG. 66, the detection level in the normal mode rises with the rise of the external power supply potential extVcc until the external power supply potential extVcc attains 2.5V. When external power supply potential extVcc exceeds 2.5V, the detection level in the normal mode is kept constant. Then, when external power supply potential extVcc exceeds 4.0V, the detection level in the normal mode again rises along with the external power supply potential extVcc. Meanwhile, the detection level in the burn in mode rises with the external power supply potential extVcc.

In this manner, according to Embodiment 47, since the detection level of boosted potential detecting circuit 81 is also increased in the burn in mode, a boosted potential V_(pp) which is higher than that of the normal mode is supplied to the internal circuit 93. Therefore, more accurate burn in test becomes possible.

[Embodiment 48]

FIG. 67 is a block diagram showing part of a DRAM in accordance with Embodiment 48 of the present invention. Referring to FIG. 67, different from FIG. 65, Embodiment 48 includes two reference potential generators 97 and 98, two boosted potential detectors 95 and 96, and an OR gate 99. Reference potential generator 97 generates a constant reference potential V_(ref) 1 based on the external power supply potential extVcc. Reference potential generator 98 is the same as that shown in FIG. 65, and it generates a reference potential V_(ref) 2 which has a prescribed relation with the external power supply potential extVcc, based on the external power supply potential extVcc .

Boosted potential detector 95 detects the boosted potential V_(pp) in the similar manner as in the above described embodiments, and determines whether or not the detected boosted potential V_(pp) has attained a prescribed detection level. When the boosted potential V_(pp) has not yet attained the prescribed detection level, an L level enable signal /GE1 is generated. The detection level of boosted potential detector 95 is determined by reference potential V_(ref) 1 generated by reference potential generator 97.

Another boosted potential detector 96 is also structured in the similar manner as the embodiments described above, and it detects a boosted potential V_(pp) generated by boosted potential generator 94 and determines whether or not the detected boosted potential V_(pp) has attained a prescribed detection level. When the boosted potential V_(pp) has not yet attained the prescribed detection level, an L level enable signal GE2 is generated. The detection level of boosted potential detector 96 is determined by the reference potential V_(ref) 2 generated by reference potential generator 98.

Enable signals /GE1 and /GE2 from boosted potential detectors 95 and 96 are both applied to OR gate 99, and OR gate 99 supplies an enable signal /GE to boosted potential generator 94. Boosted potential generator 94 is activated when the enable signal /GE is at the L level.

FIG. 68 is a graph showing reference potentials V_(ref) 1 and V_(ref) 2 as well as the detection levels of respective detectors when external power supply potential extVcc rises. As shown in FIG. 68, when the supplied external power supply potential extVcc exceeds about 2.5V, reference potential V_(ref) 1 is kept constant. Reference potential V_(ref) 2 is kept constant when the supplied external power supply potential extVcc exceeds about 2.5V, and the reference potential rises again when the external potential exceeds 4V. Since the detection level of boosted potential detector 95 is determined based on the reference potential V_(ref) 1, the detection level is also kept constant when the external power supply potential extVcc exceeds about 2.5V. Since detection level of boosted potential detector 96 is determined based on reference potential V_(ref) 2, this detection level also is kept constant when external power supply potential extVcc exceeds about 2.5V, and rises again when the external potential exceeds 4V.

When the external power supply potential extVcc is about 3V and the boosted potential V_(pp) is lower than the detection level of boosted potential detector 96, enable signals /GE1 and /GE2 both attain to the L level. Therefore, in response to the L level enable signal /GE, boosted potential generator 94 is activated. When the external power supply potential extVcc is about 3V, the boosted potential V_(pp) is lower than the detection level of boosted potential detector 95 and higher than the detection level of boosted potential detector 96, then enable signal /GE1 attains to the L level and enable signal /GE2 attains to the H level. Consequently, enable signal /GE attains to the H level, and boosted potential generator 94 is inactivated.

When external power supply potential extVcc is about 6V and the boosted potential V_(pp) is lower than the detection level of boosted potential detector 95, enable signals /GE1 and /GE2 both attain to the L level. Therefore, enable signal /GE attains to the L level, and boosted potential generator 94 is activated.

When the external power supply potential extVcc is about 6V, i.e., lower than the detection level of boosted potential detector 96 and higher than the detection level of boosted potential detector 95, then enable signal /GE1 attains to the H level and enable signal /GE2 attains to the L level. Therefore, enable signal /GE attains to the H level, and boosted potential generator 94 is inactivated.

In this manner, the detection levels of boosted potential detectors 95 and 96 have mutually different relations with external power supply potential extVcc. However, since enable signals /GE1 and /GE2 output therefrom are supplied through OR gate 99 to boosted potential generator 94 as the enable signal /GE, the boosted potential generator 94 is controlled by the detection level which is lower. Therefore, when the external power supply potential extVcc exceeds about 5.1V, the boosted potential V_(pp) is clamped at about 6V. Embodiment 48 is especially useful when the boosted potential V_(pp) is limited at a prescribed level.

[Embodiment 49]

FIG. 69 is a block diagram showing a part of a DRAM in accordance with Embodiment 49 of the present invention. Referring to FIG. 69, the DRAM includes an internal circuit 93 including a memory cell array, decoders, sense amplifiers and the like; a substrate potential generator 1000 for supplying a substrate potential V_(BB) to transistors constituting the internal circuit 93; a substrate potential detector 80 controlling the substrate potential generator 1000; and a voltage lowering circuit 32 for generating an internal power supply potential intVcc based on the external power supply potential extVcc.

Internal circuit 93 is connected between internal power supply node 500 and internal ground node 600, and performs prescribed operations based on internal power supply potential intVcc. Substrate potential generator 1000 is connected between external power supply node 300 and external ground node 400, and generates a prescribed substrate potential V_(BB). Substrate potential detector 80 has similar structure as that described in the embodiments above, and it detects substrate potential V_(BB) and determines whether or not the detected substrate potential V_(BB) has attained a prescribed detection level. When substrate potential V_(BB) has not yet attained the prescribed detection level, substrate potential generator 1000 is activated in response to an enable signal GE from substrate potential detector 80. Consequently, a constant substrate potential V_(BB) is supplied to internal circuit 93.

When internal circuitry 93 is in the standby state, a current for ensuring minimum operation of internal circuit 93 is supplied from voltage lowering circuit 32. More specifically, when internal circuit 93 is at the standby state, current supplying capability of voltage lowering circuit 32 is made lower.

When substrate potential V_(BB) becomes shallower that the prescribed detection level while the internal circuit 93 is at the standby state, substrate potential generator 1000 starts to operate. Generally, current consumption of substrate potential generating circuit 1000 is very large. However, since substrate potential generator 1000 is connected not to the internal power supply node 500 but to the external power supply node 300, the internal power supply potential intVcc never lowers, even when substrate potential generator 1000 operates.

[Embodiment 50]

FIG. 70 is a block diagram showing part of a DRAM in accordance with Embodiment 50 of the present invention. Referring to FIG. 70, different from FIG. 69, in Embodiment 50, substrate potential detector 80 is connected between internal power supply node 500 and internal ground node 600. According to Embodiment 50, even when substrate potential generator 1000 operates while internal circuit 93 is at the standby state, the internal power supply potential intVcc never lowers, since substrate potential generator 1000 is connected between external power supply node 300 and external ground node 400. As is apparent from Embodiment 50, what is necessary is that at least the substrate potential generator 1000 which consumes much current is connected to the external power supply node 300. The substrate potential detector 80 which does not consume much current may be connected to internal power supply node 500.

[Embodiment 51]

FIG. 71 is a block diagram showing a whole structure. of a DRAM in accordance with Embodiment 51 of the present invention. Referring to FIG. 71, the DRAM includes a plurality of internal circuits 931-93n, substrate potential generators 1001-100n provided corresponding to the internal circuits, and a plurality of substrate potential detectors 8001 to 800n provided corresponding to the substrate potential generators. Internal circuits 931-93n, substrate potential generators 1001-100n and substrate potential detectors 8001-800n are formed on one semiconductor chip CH formed of silicon substrate, for example.

A negative substrate potential V_(BB) 1 generated by substrate potential generator 1001 is applied to transistors constituting the internal circuit 931. The substrate potential V_(BB) 1 is detected by substrate potential detector 8001. When the detected substrate potential V_(BB) 1 is shallower than the detection level of substrate potential detecting circuit 8001, substrate potential generator 1001 is activated in response to an enable signal GE1 from substrate potential detector 8001. Therefore, a constant substrate potential V_(BB) 1 is always applied to internal circuit 931. Operations of Dther internal circuits are the same as those of internal circuit 931. However, substrate potential detectors 8001 to 800n have mutually different detection levels. Every detection level may be different from each other, or some detection levels may be the same. More specifically, at least one detection level have to be different from other detection levels.

According to Embodiment 51, since detection levels of substrate potential detectors 8001-800n are different, different substrate potentials V_(BB) 1 to V_(BB)n are supplied to internal circuits 931 to 93n. Therefore, in an internal circuit to which a shallow substrate potential is applied, transistors constituting the internal circuit operates at high speed. Meanwhile, in an internal circuit to which a deep substrate potential is supplied, there is hardly a leak current flowing through the transistors constituting the internal circuit.

[Embodiment 52]

FIG. 72 is a block diagram showing a whole structure of a DRAM in accordance with Embodiment 52 of the present invention. Referring to FIG. 72, in the DRAM, boosted potential generators 941-94n are arranged in place of substrate potential generators 1001-100n of FIG. 71. In place of substrate potential detectors 8001-800n of FIG. 71, boosted potential detectors 8101-810n are arranged. Detection levels of boosted potential detectors 8101-810n are different from each other as in Embodiment 51. Accordingly, different boosted potentials V_(pp) 1-V_(pp)n are supplied to internal circuits 931-93n.

The boosted potential supplied to the internal circuit may be used as the substrate potential of P channel MOS transistor constituting the internal circuit, or it may be used as a power supply in the internal circuit.

When the boosted potential is supplied as the substrate potential to a P channel MOS transistor, the P channel MOS transistor constituting the internal circuit operates at high speed when the internal circuit is provided with low boosted potential. Meanwhile, in an internal circuit to which high boosted potential is applied, there is hardly a leak current flowing through the P channel MOS transistor constituting the internal circuit.

When the boosted potential is supplied as the power supply in the internal circuit, in the internal circuit to which high boosted potential is supplied, the transistors constituting the internal circuit operate at high speed. The boosted potential supplied to the internal circuit may be used as the power supply in the entire internal circuit. However, it should preferably be used as the power supply at a part of the internal circuit. This is because the supplying capability of boosted potential generators 941 to 94n is generally not so large.

[Embodiment 53]

FIG. 73 is a block diagram showing a whole structure of a DRAM in accordance with Embodiment 53 of the present invention. Referring to FIG. 73, different from FIG. 71, in Embodiment 53, internal ground potential generators 1011 to 101n are arranged in place of substrate potential generators 1001-100n. In place of substrate potential detectors 8001 to 800n of FIG. 71, internal power supply potential detectors 1021-102n are arranged. Detection levels of internal ground potential detectors 1021 to 102n are different from each other. Therefore, mutually different internal ground potentials intvssl to intVssn are supplied to internal circuits 931 to 93n.

[Embodiment 54]

FIG. 74 is a block diagram showing a whole structure of a DRAM in accordance with Embodiment 54 of the present invention. Referring to FIG. 74, different from FIG. 71, in Embodiment 53, internal power supply potential generators 1031-103n are arranged in place of substrate potential generators 1001-100n. In place of substrate potential detectors 8001-800n of FIG. 71, internal power supply potential detectors 1041 to 104n are arranged. Detection levels of internal power supply potential detectors 1041-104n are different from each other. Therefore, mutually different internal power supply potentials intVcc1 to intVccn are supplied to internal circuits 931 to 93n.

As is apparent from Embodiments 53 and 54 described above, the internal potential supplied to internal circuits 931 to 93n includes substrate potential, boosted potential, internal ground potential and internal power supply potential. It is possible to combine Embodiment 53 of FIG. 73 with Embodiment 54 of FIG. 74. More specifically, a plurality of internal power supply potential generators 1031-103n and internal power supply potential detectors 1041-104n may be arranged corresponding to internal circuits 931 to 93n, as well as a plurality of internal ground potential generators 1011 to 101n and internal ground potential detectors 1021 to 102n.

[Embodiment 55]

FIG. 75 is a block diagram showing a whole structure of a DRAM in accordance with Embodiment 55 of the present invention. Referring to FIG. 75, different from FIG. 73, in Embodiment 55, tuning signals TUN1 to TUNn are respectively supplied to internal ground potential detectors 1021-102n. Detection levels of internal ground potential detectors 1021-102n change in response to tuning signals TUN1 to TUNn. Therefore, detection levels of nternal ground potential detectors 1021 to 102n may be appropriately tuned. Further, tuning may be carried out independently in each of the internal ground potential detectors. Further, one tuning signal may be applied to several internal ground potential detectors, so that detection levels of the internal ground potential detectors are set at the same value.

[Embodiment 56]

FIG. 76 is a block diagram showing a whole structure of a DRAM in accordance with Embodiment 56 of the present invention. Referring to FIG. 76, the DRAM includes, in addition to the structure shown in FIG. 73, a plurality of control circuits 1091 to 109n. The control circuits are provided for internal ground potential detectors 1021 to 102n, respectively. Control signals CNT1 to CNTn which change with time are supplied to internal ground potential detectors 1021 to 102n from control circuits 1091 to 109n. Control circuits 1091-109n may be controlled by a signal applied externally to the semiconductor chip CH, or alternatively, it may be controlled by operational temperature or an external power supply potential. When control circuit is controlled by operational temperature, it may be adapted that when the operatioral temperature exceeds a prescribed level, a control signal is applied to the internal ground potential detector, and in response to the control signal, detection level of the internal ground potential detector changes. When the control circuit is controlled by the external powers supply potential, it may be adapted such that when the external power supply potential exceeds a prescribed level, a control signal is applied from the control circuit to the internal ground potential detector, and in response to the control signal, detection level of the internal ground potential detector changes. Further, change of the detection level may be performed independently in each internal ground potential detector, or it may be performed collectively in several internal ground potential detectors.

[Embodiment 57]

FIG. 77 is an illustration showing a principle of the internal potential detecting circuit in accordance with Embodiment 57 of the present invention.

Referring to FIG. 77, the internal potential detecting circuit includes an output node 801, a constant current source 802 for supplying a constant reference current I_(ref) 1 to output node 801, and a resistance element 830 connected between output node 801 and ground node 200 and having its resistance value changed in response to a potential to be detected. Here, resistance element 830 has its resistance value increased as the detected potential lowers. Accordingly, the detection current I_(det) flowing through resistance element 830 decreases. Consequently, output node 801 is charged and an H level enable signal GE is generated.

FIG. 78 is a circuit diagram showing a specific structure of the internal potential detecting circuit shown in FIG. 77. Here, the resistance element 830 of FIG. 77 is formed by an N channel MOS transistor 831, of which gate electrode is connected to detection node 804. A boosted potential V_(pp) is applied to detection node 804. A current mirror circuit 814 is provided in the internal potential detecting circuit. The current mirror circuit 814 includes a diode connected N channel MOS transistor 815, and an N channel MOS transistor 816 having its gate electrode connected to the gate electrode of transistor 815. More specifically, in the internal potential detecting circuit shown in FIG. 78, what is provided from output node 801 is not the detection current I_(det) itself, but the current for comparison I_(cmp), which is equal to the detection current I_(det), generated by current mirror circuit 814.

In the internal potential detecting circuit in accordance with Embodiment 57, when the boosted potential V_(pp) applied to de tection node 804 lowers, conduction resistance of transistor 831 is increased, and the detection current I_(det) flowing through transistor 831 decreases. Therefore, current for comparison I_(cmp) generated by current mirror circuit 814 also decreases as the detection current I_(det). In this manner, when the boosted potential V_(pp) decreases to be lower than the prescribed detection level, current for comparison I_(cmp) becomes smaller than the reference current I_(ref) 1, hence an H level enable signal GE is generated at output node 801, and in response to the H level enable signal GE, a boosted potential generating circuit (not shown) is activated.

By the internal potential detecting circuit in accordance with Embodiment 57, whether or not the boosted potential V_(pp) has attained the prescribed level is determined. Further, since constant reference current I_(ref) 1 is supplied to output node 801 even when power supply potential Vcc fluctuates, the detection level of internal potential detecting circuit does not fluctuate.

Therefore, when the boosted potential generating circuit is controlled by using the internal potential detecting circuit, a constant boosted potential V_(pp) which is not dependent on the fluctuation of power supply potential Vcc can be obtained.

[Embodiment 58]

FIG. 79 is an illustration showing a principal of an internal potential detecting circuit in accordance with Embodiment 58 of the present invention. Referring to FIG. 79, the internal potential detecting circuit includes an output node 801, a constant current source 802 for supplying a constant reference current (−I_(ref) 1) to output node 801, and a resistance element 830 connected between power supply node 100 and output node 801 of which resistance value is changed in response to the potential to be detected.

FIG. 80 is a circuit diagram showing a specific structure of the internal potential detecting circuit shown in FIG. 79. Referring to FIG. 80, the resistance element 830 of FIG. 79 is formed by a P channel MOS transistor 832, of which gate electrode is connected to detection node 804. Substrate potential V_(BB) is applied to detection node 804. In the internal potential detecting circuit, a current mirror circuit 882 consisting of P channel MOS transistors 883 and 884 is provided. More specifically, in the internal potential detecting circuit shown in FIG. 80, not the detection current I_(det) is directly supplied to output node 801, but current for comparison I_(cmp) generated by current mirror circuit 882 in response to detection current I_(det) is directly supplied to output node 801.

In the internal potential detecting circuit, when the substrate potential V_(BB) applied to detection node 804 is increased, conduction resistance of transistor 832 increases, and accordingly, detection current I_(det) decreases. Since current for comparison I_(cmp) decreases in response to the detection current I_(det), output node 801 is discharged by the reference current I_(ref) 1. Therefore, when substrate potential V_(BB) becomes higher than the prescribed level, current for comparison I_(cmp) becomes larger than the referent current I_(ref) 1, and enable signal /GE attains to the L level. In response to the L level enable signal /GE, substrate potential generating circuit is activated.

In the internal potential detecting circuit in accordance with Embodiment 58, whether or not the substrate potential V_(BB) has attained the prescribed level is determined. Further, since constant reference current I_(ref) 1 flows from output node 801 even when ground potential Vss fluctuates, the detection level of the internal potential detecting circuit does not fluctuate. Therefore, when the substrate potential generating circuit is controlled by using the internal potential detecting circuit, a constant substrate potential V_(BB) which is not dependent on the fluctuation of ground potential Vss can be obtained.

Although the present,invention has been described and illustrated in detail, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, the spirit and scope of the present invention being limited only by the terms of the appended claims. 

What is claimed is:
 1. A potential detecting circuit for detecting a prescribed potential and determining whether the detected prescribed potential has reached a prescribed detection level or not, comprising: an output node; reference current supplying means for supplying a prescribed reference current to said output node; a detection node for receiving said prescribed potential; comparing current supplying means responsive to said prescribed potential applied to said detection node for supplying a comparing current to said output node; and a transistor having a control electrode for receiving a reference potential which is independent of a power supply voltage and is at a level different from a power supply potential, one conduction electrode connected to said detection node and the other conduction electrode connected to said comparing current supplying means; wherein current change in said transistor, corresponding to a change in said prescribed potential applied to said detection node, changes said comparing current.
 2. The potential detecting circuit according to claim 1, further comprising a resistance element connected between said one conduction electrode of said transistor and said detection node. 